/* * Cppcheck - A tool for static C/C++ code analysis * Copyright (C) 2007-2023 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 . */ #include "checkother.h" #include "errortypes.h" #include "library.h" #include "platform.h" #include "preprocessor.h" #include "settings.h" #include "standards.h" #include "fixture.h" #include "tokenize.h" #include #include #include // IWYU pragma: keep #include #include #include #include #include class TestOther : public TestFixture { public: TestOther() : TestFixture("TestOther") {} private: Settings _settings; void run() override { LOAD_LIB_2(_settings.library, "std.cfg"); TEST_CASE(emptyBrackets); TEST_CASE(zeroDiv1); TEST_CASE(zeroDiv2); TEST_CASE(zeroDiv3); TEST_CASE(zeroDiv4); TEST_CASE(zeroDiv5); TEST_CASE(zeroDiv6); TEST_CASE(zeroDiv7); // #4930 TEST_CASE(zeroDiv8); TEST_CASE(zeroDiv9); TEST_CASE(zeroDiv10); TEST_CASE(zeroDiv11); TEST_CASE(zeroDiv12); TEST_CASE(zeroDiv13); TEST_CASE(zeroDiv14); // #1169 TEST_CASE(zeroDiv15); // #8319 TEST_CASE(zeroDiv16); // #11158 TEST_CASE(zeroDiv17); // #9931 TEST_CASE(zeroDiv18); TEST_CASE(zeroDivCond); // division by zero / useless condition TEST_CASE(nanInArithmeticExpression); TEST_CASE(varScope1); TEST_CASE(varScope2); TEST_CASE(varScope3); TEST_CASE(varScope4); TEST_CASE(varScope5); TEST_CASE(varScope6); TEST_CASE(varScope7); TEST_CASE(varScope8); TEST_CASE(varScope9); // classes may have extra side-effects TEST_CASE(varScope10); // Undefined macro FOR TEST_CASE(varScope11); // #2475 - struct initialization is not inner scope TEST_CASE(varScope12); TEST_CASE(varScope13); // variable usage in inner loop TEST_CASE(varScope14); TEST_CASE(varScope15); // #4573 if-else-if TEST_CASE(varScope16); TEST_CASE(varScope17); TEST_CASE(varScope18); TEST_CASE(varScope20); // Ticket #5103 TEST_CASE(varScope21); // Ticket #5382 TEST_CASE(varScope22); // Ticket #5684 TEST_CASE(varScope23); // Ticket #6154 TEST_CASE(varScope24); // pointer / reference TEST_CASE(varScope25); // time_t TEST_CASE(varScope26); // range for loop, map TEST_CASE(varScope27); // #7733 - #if TEST_CASE(varScope28); // #10527 TEST_CASE(varScope29); // #10888 TEST_CASE(varScope30); // #8541 TEST_CASE(varScope31); // #11099 TEST_CASE(varScope32); // #11441 TEST_CASE(varScope33); TEST_CASE(oldStylePointerCast); TEST_CASE(invalidPointerCast); TEST_CASE(passedByValue); TEST_CASE(passedByValue_nonConst); TEST_CASE(passedByValue_externC); TEST_CASE(constVariable); TEST_CASE(constParameterCallback); TEST_CASE(constPointer); TEST_CASE(switchRedundantAssignmentTest); TEST_CASE(switchRedundantOperationTest); TEST_CASE(switchRedundantBitwiseOperationTest); TEST_CASE(unreachableCode); TEST_CASE(redundantContinue); TEST_CASE(suspiciousCase); TEST_CASE(suspiciousEqualityComparison); TEST_CASE(suspiciousUnaryPlusMinus); // #8004 TEST_CASE(selfAssignment); TEST_CASE(trac1132); TEST_CASE(testMisusedScopeObjectDoesNotPickFunction1); TEST_CASE(testMisusedScopeObjectDoesNotPickFunction2); TEST_CASE(testMisusedScopeObjectPicksClass); TEST_CASE(testMisusedScopeObjectPicksStruct); TEST_CASE(testMisusedScopeObjectDoesNotPickIf); TEST_CASE(testMisusedScopeObjectDoesNotPickConstructorDeclaration); TEST_CASE(testMisusedScopeObjectDoesNotPickFunctor); TEST_CASE(testMisusedScopeObjectDoesNotPickLocalClassConstructors); TEST_CASE(testMisusedScopeObjectDoesNotPickUsedObject); TEST_CASE(testMisusedScopeObjectDoesNotPickPureC); TEST_CASE(testMisusedScopeObjectDoesNotPickNestedClass); TEST_CASE(testMisusedScopeObjectInConstructor); TEST_CASE(testMisusedScopeObjectStandardType); TEST_CASE(testMisusedScopeObjectNamespace); TEST_CASE(testMisusedScopeObjectAssignment); // #11371 TEST_CASE(trac2071); TEST_CASE(trac2084); TEST_CASE(trac3693); TEST_CASE(clarifyCalculation); TEST_CASE(clarifyStatement); TEST_CASE(duplicateBranch); TEST_CASE(duplicateBranch1); // tests extracted by http://www.viva64.com/en/b/0149/ ( Comparison between PVS-Studio and cppcheck ): Errors detected in Quake 3: Arena by PVS-Studio: Fragment 2 TEST_CASE(duplicateBranch2); // empty macro TEST_CASE(duplicateBranch3); TEST_CASE(duplicateBranch4); TEST_CASE(duplicateBranch5); // make sure the Token attributes are compared TEST_CASE(duplicateBranch6); TEST_CASE(duplicateExpression1); TEST_CASE(duplicateExpression2); // ticket #2730 TEST_CASE(duplicateExpression3); // ticket #3317 TEST_CASE(duplicateExpression4); // ticket #3354 (++) TEST_CASE(duplicateExpression5); // ticket #3749 (macros with same values) TEST_CASE(duplicateExpression6); // ticket #4639 TEST_CASE(duplicateExpression7); TEST_CASE(duplicateExpression8); TEST_CASE(duplicateExpression9); // #9320 TEST_CASE(duplicateExpression10); // #9485 TEST_CASE(duplicateExpression11); // #8916 (function call) TEST_CASE(duplicateExpression12); // #10026 TEST_CASE(duplicateExpression13); // #7899 TEST_CASE(duplicateExpression14); // #9871 TEST_CASE(duplicateExpression15); // #10650 TEST_CASE(duplicateExpression16); // #10569 TEST_CASE(duplicateExpressionLoop); TEST_CASE(duplicateValueTernary); TEST_CASE(duplicateExpressionTernary); // #6391 TEST_CASE(duplicateExpressionTemplate); // #6930 TEST_CASE(duplicateExpressionCompareWithZero); TEST_CASE(oppositeExpression); TEST_CASE(duplicateVarExpression); TEST_CASE(duplicateVarExpressionUnique); TEST_CASE(duplicateVarExpressionAssign); TEST_CASE(duplicateVarExpressionCrash); TEST_CASE(multiConditionSameExpression); TEST_CASE(checkSignOfUnsignedVariable); TEST_CASE(checkSignOfPointer); TEST_CASE(checkSuspiciousSemicolon1); TEST_CASE(checkSuspiciousSemicolon2); TEST_CASE(checkSuspiciousSemicolon3); TEST_CASE(checkSuspiciousComparison); TEST_CASE(checkInvalidFree); TEST_CASE(checkRedundantCopy); TEST_CASE(checkNegativeShift); TEST_CASE(incompleteArrayFill); TEST_CASE(redundantVarAssignment); TEST_CASE(redundantVarAssignment_trivial); TEST_CASE(redundantVarAssignment_struct); TEST_CASE(redundantVarAssignment_7133); TEST_CASE(redundantVarAssignment_stackoverflow); TEST_CASE(redundantVarAssignment_lambda); TEST_CASE(redundantVarAssignment_loop); TEST_CASE(redundantVarAssignment_after_switch); TEST_CASE(redundantVarAssignment_pointer); TEST_CASE(redundantVarAssignment_pointer_parameter); TEST_CASE(redundantVarAssignment_array); TEST_CASE(redundantVarAssignment_switch_break); TEST_CASE(redundantInitialization); TEST_CASE(redundantMemWrite); TEST_CASE(varFuncNullUB); TEST_CASE(checkCastIntToCharAndBack); // ticket #160 TEST_CASE(checkCommaSeparatedReturn); TEST_CASE(checkPassByReference); TEST_CASE(checkComparisonFunctionIsAlwaysTrueOrFalse); TEST_CASE(integerOverflow); // #5895 TEST_CASE(redundantPointerOp); TEST_CASE(test_isSameExpression); TEST_CASE(raceAfterInterlockedDecrement); TEST_CASE(testUnusedLabel); TEST_CASE(testEvaluationOrder); TEST_CASE(testEvaluationOrderSelfAssignment); TEST_CASE(testEvaluationOrderMacro); TEST_CASE(testEvaluationOrderSequencePointsFunctionCall); TEST_CASE(testEvaluationOrderSequencePointsComma); TEST_CASE(testEvaluationOrderSizeof); TEST_CASE(testUnsignedLessThanZero); TEST_CASE(doubleMove1); TEST_CASE(doubleMoveMemberInitialization1); TEST_CASE(doubleMoveMemberInitialization2); TEST_CASE(doubleMoveMemberInitialization3); // #9974 TEST_CASE(moveAndAssign1); TEST_CASE(moveAndAssign2); TEST_CASE(moveAssignMoveAssign); TEST_CASE(moveAndReset1); TEST_CASE(moveAndReset2); TEST_CASE(moveResetMoveReset); TEST_CASE(moveAndFunctionParameter); TEST_CASE(moveAndFunctionParameterReference); TEST_CASE(moveAndFunctionParameterConstReference); TEST_CASE(moveAndFunctionParameterUnknown); TEST_CASE(moveAndReturn); TEST_CASE(moveAndClear); TEST_CASE(movedPointer); TEST_CASE(moveAndAddressOf); TEST_CASE(partiallyMoved); TEST_CASE(moveAndLambda); TEST_CASE(moveInLoop); TEST_CASE(moveCallback); TEST_CASE(moveClassVariable); TEST_CASE(forwardAndUsed); TEST_CASE(moveAndReference); TEST_CASE(moveForRange); TEST_CASE(funcArgNamesDifferent); TEST_CASE(funcArgOrderDifferent); TEST_CASE(cpp11FunctionArgInit); // #7846 - "void foo(int declaration = {}) {" TEST_CASE(shadowVariables); TEST_CASE(knownArgument); TEST_CASE(knownArgumentHiddenVariableExpression); TEST_CASE(knownArgumentTernaryOperator); TEST_CASE(checkComparePointers); TEST_CASE(unusedVariableValueTemplate); // #8994 TEST_CASE(moduloOfOne); TEST_CASE(sameExpressionPointers); TEST_CASE(checkOverlappingWrite); TEST_CASE(constVariableArrayMember); // #10371 } #define check(...) check_(__FILE__, __LINE__, __VA_ARGS__) void check_(const char* file, int line, const char code[], const char *filename = nullptr, bool inconclusive = true, bool runSimpleChecks=true, bool verbose=false, Settings* settings = nullptr) { // Clear the error buffer.. errout.str(""); if (!settings) { settings = &_settings; } settings->severity.enable(Severity::style); settings->severity.enable(Severity::warning); settings->severity.enable(Severity::portability); settings->severity.enable(Severity::performance); settings->standards.c = Standards::CLatest; settings->standards.cpp = Standards::CPPLatest; settings->certainty.setEnabled(Certainty::inconclusive, inconclusive); settings->verbose = verbose; Preprocessor preprocessor(*settings); // Tokenize.. Tokenizer tokenizer(settings, this, &preprocessor); std::istringstream istr(code); ASSERT_LOC(tokenizer.tokenize(istr, filename ? filename : "test.cpp"), file, line); // Check.. runChecks(&tokenizer, settings, this); (void)runSimpleChecks; // TODO Remove this } void check_(const char* file, int line, const char code[], Settings *s) { check_(file, line, code, "test.cpp", true, true, false, s); } void checkP(const char code[], const char *filename = "test.cpp") { // Clear the error buffer.. errout.str(""); Settings* settings = &_settings; settings->severity.enable(Severity::style); settings->severity.enable(Severity::warning); settings->severity.enable(Severity::portability); settings->severity.enable(Severity::performance); settings->standards.c = Standards::CLatest; settings->standards.cpp = Standards::CPPLatest; settings->certainty.enable(Certainty::inconclusive); // Raw tokens.. std::vector files(1, filename); std::istringstream istr(code); const simplecpp::TokenList tokens1(istr, files, files[0]); // Preprocess.. simplecpp::TokenList tokens2(files); std::map filedata; simplecpp::preprocess(tokens2, tokens1, files, filedata, simplecpp::DUI()); Preprocessor preprocessor(*settings); preprocessor.setDirectives(tokens1); // Tokenizer.. Tokenizer tokenizer(settings, this, &preprocessor); tokenizer.createTokens(std::move(tokens2)); tokenizer.simplifyTokens1(""); // Check.. runChecks(&tokenizer, settings, this); } void checkInterlockedDecrement(const char code[]) { Settings settings; settings.platform.type = cppcheck::Platform::Type::Win32A; check(code, nullptr, false, true, false, &settings); } void emptyBrackets() { check("{\n" "}"); ASSERT_EQUALS("", errout.str()); } void zeroDiv1() { // floating point division by zero => no error check("void foo() {\n" " cout << 1. / 0;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo() {\n" " cout << 42 / (double)0;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo() {\n" " cout << 42 / (float)0;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo() {\n" " cout << 42 / (int)0;\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (error) Division by zero.\n", errout.str()); } void zeroDiv2() { check("void foo()\n" "{\n" " int sum = 0;\n" " for(int i = 0; i < n; i ++)\n" " {\n" " sum += i;\n" " }\n" " cout< do not warn check("void f() {\n" " int a = x/2*3/0;\n" " int b = y/2*3%0;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(int x, int y) {\n" " int a = x/2*3/0;\n" " int b = y/2*3%0;\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (error) Division by zero.\n" "[test.cpp:3]: (error) Division by zero.\n", errout.str()); } void zeroDiv8() { // #5584 - FP when function is unknown check("void f() {\n" " int a = 0;\n" " do_something(a);\n" " return 4 / a;\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (error, inconclusive) Division by zero.\n", errout.str()); } void zeroDiv9() { // #6403 FP zerodiv - inside protecting if-clause check("void foo() {\n" " double fStepHelp = 0;\n" " if( (rOuterValue >>= fStepHelp) ) {\n" " if( fStepHelp != 0.0) {\n" " double fStepMain = 1;\n" " sal_Int32 nIntervalCount = static_cast< sal_Int32 >(fStepMain / fStepHelp);\n" " }\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); } void zeroDiv10() { // #5402 false positive: (error) Division by zero -- with boost::format check("int main() {\n" " std::cout\n" " << boost::format(\" %d :: %s <> %s\") % 0 % \"a\" % \"b\"\n" " << std::endl;\n" " return 0;\n" "}"); ASSERT_EQUALS("", errout.str()); } void zeroDiv11() { check("void f(int a) {\n" " int res = (a+2)/0;\n" " int res = (a*2)/0;\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (error) Division by zero.\n" "[test.cpp:3]: (error) Division by zero.\n", errout.str()); check("void f() {\n" " int res = (a+2)/0;\n" " int res = (a*2)/0;\n" "}"); ASSERT_EQUALS("", errout.str()); } void zeroDiv12() { // #8141 check("intmax_t f() {\n" " return 1 / imaxabs(0);\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (error) Division by zero.\n", errout.str()); } void zeroDiv13() { // #7324 check("int f () {\n" " int dividend = 10;\n" " int divisor = 1;\n" " dividend = dividend / (--divisor);\n" " return dividend;\n" "}\n"); ASSERT_EQUALS("[test.cpp:4]: (error) Division by zero.\n", errout.str()); } void zeroDiv14() { check("void f() {\n" // #1169 " double dx = 1.;\n" " int ix = 1;\n" " int i = 1;\n" " std::cout << ix / (i >> 1) << std::endl;\n" " std::cout << dx / (i >> 1) << std::endl;\n" "}\n"); ASSERT_EQUALS("[test.cpp:5]: (error) Division by zero.\n", errout.str()); } void zeroDiv15() { // #8319 check("int f(int i) { return i - 1; }\n" "int f() {\n" " const int d = 1;\n" " const int r = 1 / f(d);\n" " return r;\n" "}\n"); ASSERT_EQUALS("[test.cpp:4]: (error) Division by zero.\n", errout.str()); } // #11158 void zeroDiv16() { check("int f(int i) {\n" " int number = 10, a = 0;\n" " for (int count = 0; count < 2; count++) {\n" " a += (i / number) % 10;\n" " number = number / 10;\n" " }\n" " return a;\n" "}\n"); ASSERT_EQUALS("", errout.str()); check("int f(int i) {\n" " int number = 10, a = 0;\n" " for (int count = 0; count < 2; count++) {\n" " int x = number / 10;\n" " a += (i / number) % 10;\n" " number = x;\n" " }\n" " return a;\n" "}\n"); ASSERT_EQUALS("", errout.str()); } void zeroDiv17() { // #9931 check("int f(int len) {\n" " int sz = sizeof(void*[255]) / 255;\n" " int x = len % sz;\n" " return x;\n" "}\n"); ASSERT_EQUALS("", errout.str()); } void zeroDiv18() { check("int f(int x, int y) {\n" " if (x == y) {}\n" " return 1 / (x-y);\n" "}\n"); ASSERT_EQUALS( "[test.cpp:2] -> [test.cpp:3]: (warning) Either the condition 'x==y' is redundant or there is division by zero at line 3.\n", errout.str()); } void zeroDivCond() { check("void f(unsigned int x) {\n" " int y = 17 / x;\n" " if (x > 0) {}\n" "}"); ASSERT_EQUALS("[test.cpp:3] -> [test.cpp:2]: (warning) Either the condition 'x>0' is redundant or there is division by zero at line 2.\n", errout.str()); check("void f(unsigned int x) {\n" " int y = 17 / x;\n" " if (x >= 1) {}\n" "}"); ASSERT_EQUALS("[test.cpp:3] -> [test.cpp:2]: (warning) Either the condition 'x>=1' is redundant or there is division by zero at line 2.\n", errout.str()); check("void f(int x) {\n" " int y = 17 / x;\n" " if (x == 0) {}\n" "}"); ASSERT_EQUALS("[test.cpp:3] -> [test.cpp:2]: (warning) Either the condition 'x==0' is redundant or there is division by zero at line 2.\n", errout.str()); check("void f(unsigned int x) {\n" " int y = 17 / x;\n" " if (x != 0) {}\n" "}"); ASSERT_EQUALS("[test.cpp:3] -> [test.cpp:2]: (warning) Either the condition 'x!=0' is redundant or there is division by zero at line 2.\n", errout.str()); // function call check("void f1(int x, int y) { c=x/y; }\n" "void f2(unsigned int y) {\n" " f1(123,y);\n" " if (y>0){}\n" "}"); ASSERT_EQUALS( "[test.cpp:4] -> [test.cpp:1]: (warning) Either the condition 'y>0' is redundant or there is division by zero at line 1.\n", errout.str()); // avoid false positives when variable is changed after division check("void f() {\n" " unsigned int x = do_something();\n" " int y = 17 / x;\n" " x = some+calculation;\n" " if (x != 0) {}\n" "}"); ASSERT_EQUALS("", errout.str()); { // function is called that might modify global variable check("void do_something();\n" "int x;\n" "void f() {\n" " int y = 17 / x;\n" " do_something();\n" " if (x != 0) {}\n" "}"); ASSERT_EQUALS("", errout.str()); // function is called. but don't care, variable is local check("void do_something();\n" "void f() {\n" " int x = some + calculation;\n" " int y = 17 / x;\n" " do_something();\n" " if (x != 0) {}\n" "}"); ASSERT_EQUALS("[test.cpp:6] -> [test.cpp:4]: (warning) Either the condition 'x!=0' is redundant or there is division by zero at line 4.\n", errout.str()); } check("void do_something(int value);\n" "void f(int x) {\n" " int y = 17 / x;\n" " do_something(x);\n" "}"); ASSERT_EQUALS("", errout.str()); check("int x;\n" "void f() {\n" " int y = 17 / x;\n" " while (y || x == 0) { x--; }\n" "}"); ASSERT_EQUALS("", errout.str()); // ticket 5033 segmentation fault (valid code) in CheckOther::checkZeroDivisionOrUselessCondition check("void f() {\n" "double* p1= new double[1];\n" "double* p2= new double[1];\n" "double* p3= new double[1];\n" "double* pp[3] = {p1,p2,p3};\n" "}"); ASSERT_EQUALS("", errout.str()); // #5105 - FP check("int f(int a, int b) {\n" " int r = a / b;\n" " if (func(b)) {}\n" "}"); ASSERT_EQUALS("", errout.str()); // Unknown types for b and c --> do not warn check("int f(int d) {\n" " int r = (a?b:c) / d;\n" " if (d == 0) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("int f(int a) {\n" " int r = a ? 1 / a : 0;\n" " if (a == 0) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("int f(int a) {\n" " int r = (a == 0) ? 0 : 1 / a;\n" " if (a == 0) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("int g();\n" "void f(int b) {\n" " int x = g();\n" " if (x == 0) {}\n" " else if (x > 0) {}\n" " else\n" " a = b / -x;\n" "}"); ASSERT_EQUALS("", errout.str()); check("struct A {\n" " int x;\n" "};\n" "int f(A* a) {\n" " if (a->x == 0) \n" " a->x = 1;\n" " return 1/a->x;\n" "}\n"); ASSERT_EQUALS("", errout.str()); // #10049 check("int f(int argc) {\n" " int quotient, remainder;\n" " remainder = argc % 2;\n" " argc = 2;\n" " quotient = argc;\n" " if (quotient != 0) \n" " return quotient;\n" " return remainder;\n" "}\n"); ASSERT_EQUALS("", errout.str()); // #11315 checkP("#define STATIC_ASSERT(c) \\\n" "do { enum { sa = 1/(int)(!!(c)) }; } while (0)\n" "void f() {\n" " STATIC_ASSERT(sizeof(int) == sizeof(FOO));\n" "}\n"); ASSERT_EQUALS("", errout.str()); } void nanInArithmeticExpression() { check("void f()\n" "{\n" " double x = 3.0 / 0.0 + 1.0;\n" " printf(\"%f\", x);\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (style) Using NaN/Inf in a computation.\n", errout.str()); check("void f()\n" "{\n" " double x = 3.0 / 0.0 - 1.0;\n" " printf(\"%f\", x);\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (style) Using NaN/Inf in a computation.\n", errout.str()); check("void f()\n" "{\n" " double x = 1.0 + 3.0 / 0.0;\n" " printf(\"%f\", x);\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (style) Using NaN/Inf in a computation.\n", errout.str()); check("void f()\n" "{\n" " double x = 1.0 - 3.0 / 0.0;\n" " printf(\"%f\", x);\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (style) Using NaN/Inf in a computation.\n", errout.str()); check("void f()\n" "{\n" " double x = 3.0 / 0.0;\n" " printf(\"%f\", x);\n" "}"); ASSERT_EQUALS("", errout.str()); } void varScope1() { check("unsigned short foo()\n" "{\n" " test_client CClient;\n" " try\n" " {\n" " if (CClient.Open())\n" " {\n" " return 0;\n" " }\n" " }\n" " catch (...)\n" " {\n" " return 2;\n" " }\n" "\n" " try\n" " {\n" " CClient.Close();\n" " }\n" " catch (...)\n" " {\n" " return 2;\n" " }\n" "\n" " return 1;\n" "}"); ASSERT_EQUALS("", errout.str()); } void varScope2() { check("int foo()\n" "{\n" " Error e;\n" " e.SetValue(12);\n" " throw e;\n" "}"); ASSERT_EQUALS("", errout.str()); } void varScope3() { check("void foo()\n" "{\n" " int i;\n" " int *p = 0;\n" " if (abc)\n" " {\n" " p = &i;\n" " }\n" " *p = 1;\n" "}"); ASSERT_EQUALS("", errout.str()); } void varScope4() { check("void foo()\n" "{\n" " int i;\n" "}"); ASSERT_EQUALS("", errout.str()); } void varScope5() { check("void f(int x)\n" "{\n" " int i = 0;\n" " if (x) {\n" " for ( ; i < 10; ++i) ;\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (style) The scope of the variable 'i' can be reduced.\n", errout.str()); check("void f(int x) {\n" " const unsigned char i = 0;\n" " if (x) {\n" " for ( ; i < 10; ++i) ;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(int x)\n" "{\n" " int i = 0;\n" " if (x) {b()}\n" " else {\n" " for ( ; i < 10; ++i) ;\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (style) The scope of the variable 'i' can be reduced.\n", errout.str()); } void varScope6() { check("void f(int x)\n" "{\n" " int i = x;\n" " if (a) {\n" " x++;\n" " }\n" " if (b) {\n" " c(i);\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" // #5398 " bool success = false;\n" " int notReducable(someClass.getX(&success));\n" " if (success) {\n" " foo(notReducable);\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(Test &test) {\n" " int& x = test.getData();\n" " if (test.process())\n" " x = 0;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f()\n" "{\n" "int foo = 0;\n" "std::vector vec(10);\n" "BOOST_FOREACH(int& i, vec)\n" "{\n" " foo += 1;\n" " if(foo == 10)\n" " {\n" " return 0;\n" " }\n" "}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(int &x)\n" "{\n" " int n = 1;\n" " do\n" " {\n" " ++n;\n" " ++x;\n" " } while (x);\n" "}"); ASSERT_EQUALS("", errout.str()); } void varScope7() { check("void f(int x)\n" "{\n" " int y = 0;\n" " b(y);\n" " if (x) {\n" " y++;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); } void varScope8() { check("void test() {\n" " float edgeResistance=1;\n" " std::vector edges;\n" " BOOST_FOREACH(int edge, edges) {\n" " edgeResistance = (edge+1) / 2.0;\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) The scope of the variable 'edgeResistance' can be reduced.\n", errout.str()); } void varScope9() { // classes may have extra side effects check("class fred {\n" "public:\n" " void x();\n" "};\n" "void test(int a) {\n" " fred f;\n" " if (a == 2) {\n" " f.x();\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); } void varScope10() { check("int f()\n" "{\n" " int x = 0;\n" " FOR {\n" " foo(x++);\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); } void varScope11() { check("int f() {\n" " int x = 0;\n" " AB ab = { x, 0 };\n" "}"); ASSERT_EQUALS("", errout.str()); check("int f() {\n" " int x = 0;\n" " if (a == 0) { ++x; }\n" " AB ab = { x, 0 };\n" "}"); ASSERT_EQUALS("", errout.str()); check("int f() {\n" " int x = 0;\n" " if (a == 0) { ++x; }\n" " if (a == 1) { AB ab = { x, 0 }; }\n" "}"); ASSERT_EQUALS("", errout.str()); } void varScope12() { check("void f(int x) {\n" " int i[5];\n" " int* j = y;\n" " if (x)\n" " foo(i);\n" " foo(j);\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) The scope of the variable 'i' can be reduced.\n", errout.str()); check("void f(int x) {\n" " int i[5];\n" " int* j;\n" " if (x)\n" " j = i;\n" " foo(j);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(int x) {\n" " const bool b = true;\n" " x++;\n" " if (x == 5)\n" " foo(b);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(int x) {\n" " const bool b = x;\n" " x++;\n" " if (x == 5)\n" " foo(b);\n" "}"); ASSERT_EQUALS("", errout.str()); } void varScope13() { // #2770 check("void f() {\n" " int i = 0;\n" " forever {\n" " if (i++ == 42) { break; }\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); } void varScope14() { // #3941 check("void f() {\n" " const int i( foo());\n" " if(a) {\n" " for ( ; i < 10; ++i) ;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); } void varScope15() { // #4573 check("void f() {\n" " int a,b,c;\n" " if (a);\n" " else if(b);\n" " else if(c);\n" " else;\n" "}", nullptr, false); ASSERT_EQUALS("", errout.str()); } void varScope16() { check("void f() {\n" " int a = 0;\n" " while((++a) < 56) {\n" " foo();\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " int a = 0;\n" " do {\n" " foo();\n" " } while((++a) < 56);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " int a = 0;\n" " do {\n" " a = 64;\n" " foo(a);\n" " } while((++a) < 56);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " int a = 0;\n" " do {\n" " a = 64;\n" " foo(a);\n" " } while(z());\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) The scope of the variable 'a' can be reduced.\n", errout.str()); } void varScope17() { check("void f() {\n" " int x;\n" " if (a) {\n" " x = stuff(x);\n" " morestuff(x);\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) The scope of the variable 'x' can be reduced.\n", errout.str()); check("void f() {\n" " int x;\n" " if (a) {\n" " x = stuff(x);\n" " morestuff(x);\n" " }\n" " if (b) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) The scope of the variable 'x' can be reduced.\n", errout.str()); } void varScope18() { check("void f() {\n" " short x;\n" "\n" " switch (ab) {\n" " case A:\n" " break;\n" " case B:\n" " default:\n" " break;\n" " }\n" "\n" " if (c) {\n" " x = foo();\n" " do_something(x);\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) The scope of the variable 'x' can be reduced.\n", errout.str()); check("void f() {\n" " short x;\n" "\n" " switch (ab) {\n" " case A:\n" " x = 10;\n" " break;\n" " case B:\n" " default:\n" " break;\n" " }\n" "\n" " if (c) {\n" " x = foo();\n" " do_something(x);\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " short x;\n" "\n" " switch (ab) {\n" " case A:\n" " if(c)\n" " do_something(x);\n" " break;\n" " case B:\n" " default:\n" " break;\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) The scope of the variable 'x' can be reduced.\n", errout.str()); check("void f() {\n" " short x;\n" "\n" " switch (ab) {\n" " case A:\n" " if(c)\n" " do_something(x);\n" " break;\n" " case B:\n" " default:\n" " if(d)\n" " do_something(x);\n" " break;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); } void varScope20() { // Ticket #5103 - constant variable only used in inner scope check("int f(int a) {\n" " const int x = 234;\n" " int b = a;\n" " if (b > 32) b = x;\n" " return b;\n" "}"); ASSERT_EQUALS("", errout.str()); } void varScope21() { // Ticket #5382 - initializing two-dimensional array check("int test() {\n" " int test_value = 3;\n" " int test_array[1][1] = { { test_value } };\n" " return sizeof(test_array);\n" "}"); ASSERT_EQUALS("", errout.str()); } void varScope22() { // Ticket #5684 - "The scope of the variable 'p' can be reduced" - But it can not. check("void foo() {\n" " int* p( 42 );\n" " int i = 0;\n" " while ( i != 100 ) {\n" " *p = i;\n" " ++p;\n" " ++i;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); // try to avoid an obvious false negative after applying the fix for the example above: check("void foo() {\n" " int* p( 42 );\n" " int i = 0;\n" " int dummy = 0;\n" " while ( i != 100 ) {\n" " p = & dummy;\n" " *p = i;\n" " ++p;\n" " ++i;\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) The scope of the variable 'p' can be reduced.\n", errout.str()); } void varScope23() { // #6154: Don't suggest to reduce scope if inner scope is a lambda check("int main() {\n" " size_t myCounter = 0;\n" " Test myTest([&](size_t aX){\n" " std::cout << myCounter += aX << std::endl;\n" " });\n" "}"); ASSERT_EQUALS("", errout.str()); } void varScope24() { check("void f(Foo x) {\n" " Foo &r = x;\n" " if (cond) {\n" " r.dostuff();\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) The scope of the variable 'r' can be reduced.\n", errout.str()); check("void f(Foo x) {\n" " Foo foo = x;\n" " if (cond) {\n" " foo.dostuff();\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); } void varScope25() { check("void f() {\n" " time_t currtime;\n" " if (a) {\n" " currtime = time(&dummy);\n" " if (currtime > t) {}\n" " }\n" "}", "test.c"); ASSERT_EQUALS("[test.c:2]: (style) The scope of the variable 'currtime' can be reduced.\n", errout.str()); } void varScope26() { check("void f(const std::map &m) {\n" " for (auto it : m) {\n" " if (cond1) {\n" " int& key = it.first;\n" " if (cond2) { dostuff(key); }\n" " }\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); } void varScope27() { checkP("void f() {\n" " int x = 0;\n" "#ifdef X\n" "#endif\n" " if (id == ABC) { return x; }\n" "}"); ASSERT_EQUALS("", errout.str()); checkP("void f() {\n" "#ifdef X\n" "#endif\n" " int x = 0;\n" " if (id == ABC) { return x; }\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (style) The scope of the variable 'x' can be reduced.\n", errout.str()); } void varScope28() { check("void f() {\n" // #10527 " int i{};\n" " if (double d = g(i); d == 1.0) {}\n" "}\n"); ASSERT_EQUALS("", errout.str()); } void varScope29() { // #10888 check("enum E { E0 };\n" "struct S { int i; };\n" "void f(int b) {\n" " enum E e;\n" " struct S s;\n" " if (b) {\n" " e = E0;\n" " s.i = 0;\n" " g(e, s);\n" " }\n" "}\n", "test.c"); ASSERT_EQUALS("[test.c:4]: (style) The scope of the variable 'e' can be reduced.\n" "[test.c:5]: (style) The scope of the variable 's' can be reduced.\n", errout.str()); check("void f(bool b) {\n" " std::string s;\n" " if (b) {\n" " s = \"abc\";\n" " g(s);\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) The scope of the variable 's' can be reduced.\n", errout.str()); check("auto foo(std::vector& vec, bool flag) {\n" " std::vector dummy;\n" " std::vector::iterator iter;\n" " if (flag)\n" " iter = vec.begin();\n" " else {\n" " dummy.push_back(42);\n" " iter = dummy.begin();\n" " }\n" " return *iter;\n" "}"); ASSERT_EQUALS("[test.cpp:1]: (style) Parameter 'vec' can be declared as reference to const\n", errout.str()); check("auto& foo(std::vector& vec, bool flag) {\n" " std::vector dummy;\n" " std::vector::iterator iter;\n" " if (flag)\n" " iter = vec.begin();\n" " else {\n" " dummy.push_back(42);\n" " iter = dummy.begin();\n" " }\n" " return *iter;\n" "}"); ASSERT_EQUALS("", errout.str()); } void varScope30() { // #8541 check("bool f(std::vector& v, int i) {\n" " int n = 0;\n" " bool b = false;\n" " std::for_each(v.begin(), v.end(), [&](int j) {\n" " if (j == i) {\n" " ++n;\n" " if (n > 5)\n" " b = true;\n" " }\n" " });\n" " return b;\n" "}\n"); ASSERT_EQUALS("", errout.str()); } void varScope31() { // #11099 check("bool g(std::vector&);\n" "void h(std::vector);\n" "void f0(std::vector v) {\n" " std::vector w{ v };\n" " bool b = g(v);\n" " if (b)\n" " h(w);\n" " h(v);\n" "}\n" "void f1(std::vector v) {\n" " std::vector w{ v.begin(), v.end() };\n" " bool b = g(v);\n" " if (b)\n" " h(w);\n" " h(v);\n" "}\n" "void f2(std::vector v) {\n" " std::vector w{ 10, 0, std::allocator() };\n" // FN " bool b = g(v);\n" " if (b)\n" " h(w);\n" " h(v);\n" "}\n" "void f3(std::vector v) {\n" " std::vector w{ 10, 0 };\n" // warn " bool b = g(v);\n" " if (b)\n" " h(w);\n" " h(v);\n" "}\n" "void f4(std::vector v) {\n" " std::vector w{ 10 };\n" // warn " bool b = g(v);\n" " if (b)\n" " h(w);\n" " h(v);\n" "}\n" "void f5(std::vector v) {\n" " std::vector w(v);\n" " bool b = g(v);\n" " if (b)\n" " h(w);\n" " h(v);\n" "}\n" "void f6(std::vector v) {\n" " std::vector w(v.begin(), v.end());\n" " bool b = g(v);\n" " if (b)\n" " h(w);\n" " h(v);\n" "}\n" "void f7(std::vector v) {\n" " std::vector w(10, 0, std::allocator);\n" // FN " bool b = g(v);\n" " if (b)\n" " h(w);\n" " h(v);\n" "}\n" "void f8(std::vector v) {\n" " std::vector w(10, 0);\n" // warn " bool b = g(v);\n" " if (b)\n" " h(w);\n" " h(v);\n" "}\n" "void f9(std::vector v) {\n" " std::vector w(10);\n" // warn " bool b = g(v);\n" " if (b)\n" " h(w);\n" " h(v);\n" "}\n" "void f10(std::vector v) {\n" " std::vector w{};\n" // warn " bool b = g(v);\n" " if (b)\n" " h(w);\n" " h(v);\n" "}\n"); ASSERT_EQUALS("[test.cpp:25]: (style) The scope of the variable 'w' can be reduced.\n" "[test.cpp:32]: (style) The scope of the variable 'w' can be reduced.\n" "[test.cpp:60]: (style) The scope of the variable 'w' can be reduced.\n" "[test.cpp:67]: (style) The scope of the variable 'w' can be reduced.\n" "[test.cpp:74]: (style) The scope of the variable 'w' can be reduced.\n", errout.str()); } void varScope32() { // #11441 check("template \n" "std::vector g(F, const std::vector&);\n" "void f(const std::vector&v) {\n" " std::vector w;\n" " for (auto x : v)\n" " w = g([&]() { x; }, w);\n" "}\n"); ASSERT_EQUALS("[test.cpp:6]: (warning) Unused variable value 'x'\n", errout.str()); } void varScope33() { // #11131 check("struct S {\n" " const std::string& getStr() const;\n" " void mutate();\n" " bool getB() const;\n" "};\n" "void g(S& s) {\n" " std::string str = s.getStr();\n" " s.mutate();\n" " if (s.getB()) {\n" " if (str == \"abc\") {}\n" " }\n" "}\n" "void g(char* s, bool b) {\n" " int i = strlen(s);\n" " s[0] = '\\0';\n" " if (b) {\n" " if (i == 5) {}\n" " }\n" "}\n" "void f(const S& s) {\n" " std::string str = s.getStr();\n" " std::string str2{ s.getStr() };\n" " std::string str3(s.getStr());\n" " if (s.getB()) {\n" " if (str == \"abc\") {}\n" " if (str2 == \"abc\") {}\n" " if (str3 == \"abc\") {}\n" " }\n" "}\n" "void f(const char* s, bool b) {\n" " int i = strlen(s);\n" " if (b) {\n" " if (i == 5) {}\n" " }\n" "}\n" "void f(int j, bool b) {\n" " int k = j;\n" " if (b) {\n" " if (k == 5) {}\n" " }\n" "}\n"); ASSERT_EQUALS("[test.cpp:21]: (style) The scope of the variable 'str' can be reduced.\n" "[test.cpp:22]: (style) The scope of the variable 'str2' can be reduced.\n" "[test.cpp:23]: (style) The scope of the variable 'str3' can be reduced.\n" "[test.cpp:31]: (style) The scope of the variable 'i' can be reduced.\n" "[test.cpp:37]: (style) The scope of the variable 'k' can be reduced.\n", errout.str()); } #define checkOldStylePointerCast(code) checkOldStylePointerCast_(code, __FILE__, __LINE__) void checkOldStylePointerCast_(const char code[], const char* file, int line) { // Clear the error buffer.. errout.str(""); // #5560 - set c++03 const Settings settings = settingsBuilder().severity(Severity::style).cpp(Standards::CPP03).build(); Preprocessor preprocessor(settings); // Tokenize.. Tokenizer tokenizerCpp(&settings, this, &preprocessor); std::istringstream istr(code); ASSERT_LOC(tokenizerCpp.tokenize(istr, "test.cpp"), file, line); CheckOther checkOtherCpp(&tokenizerCpp, &settings, this); checkOtherCpp.warningOldStylePointerCast(); } void oldStylePointerCast() { checkOldStylePointerCast("class Base;\n" "void foo()\n" "{\n" " Base * b = (Base *) derived;\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (style) C-style pointer casting\n", errout.str()); checkOldStylePointerCast("class Base;\n" "void foo()\n" "{\n" " Base * b = (const Base *) derived;\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (style) C-style pointer casting\n", errout.str()); checkOldStylePointerCast("class Base;\n" "void foo()\n" "{\n" " Base * b = (const Base * const) derived;\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (style) C-style pointer casting\n", errout.str()); checkOldStylePointerCast("class Base;\n" "void foo()\n" "{\n" " Base * b = (volatile Base *) derived;\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (style) C-style pointer casting\n", errout.str()); checkOldStylePointerCast("class Base;\n" "void foo()\n" "{\n" " Base * b = (volatile Base * const) derived;\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (style) C-style pointer casting\n", errout.str()); checkOldStylePointerCast("class Base;\n" "void foo()\n" "{\n" " Base * b = (const volatile Base *) derived;\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (style) C-style pointer casting\n", errout.str()); checkOldStylePointerCast("class Base;\n" "void foo()\n" "{\n" " Base * b = (const volatile Base * const) derived;\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (style) C-style pointer casting\n", errout.str()); checkOldStylePointerCast("class Base;\n" "void foo()\n" "{\n" " Base * b = (const Base *) ( new Derived() );\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (style) C-style pointer casting\n", errout.str()); checkOldStylePointerCast("class Base;\n" "void foo()\n" "{\n" " Base * b = (const Base *) new Derived();\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (style) C-style pointer casting\n", errout.str()); checkOldStylePointerCast("class Base;\n" "void foo()\n" "{\n" " Base * b = (const Base *) new short[10];\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (style) C-style pointer casting\n", errout.str()); checkOldStylePointerCast("class B;\n" "class A\n" "{\n" " virtual void abc(B *) const = 0;\n" "}"); ASSERT_EQUALS("", errout.str()); checkOldStylePointerCast("class B;\n" "class A\n" "{\n" " virtual void abc(const B *) const = 0;\n" "}"); ASSERT_EQUALS("", errout.str()); // #3630 checkOldStylePointerCast("class SomeType;\n" "class X : public Base {\n" " X() : Base((SomeType*)7) {}\n" "};"); ASSERT_EQUALS("[test.cpp:3]: (style) C-style pointer casting\n", errout.str()); checkOldStylePointerCast("class SomeType;\n" "class X : public Base {\n" " X() : Base((SomeType*)var) {}\n" "};"); ASSERT_EQUALS("[test.cpp:3]: (style) C-style pointer casting\n", errout.str()); checkOldStylePointerCast("class SomeType;\n" "class X : public Base {\n" " X() : Base((SomeType*)0) {}\n" "};"); ASSERT_EQUALS("", errout.str()); // #5560 checkOldStylePointerCast("class C;\n" "\n" "class B\n" "{ virtual G* createGui(S*, C*) const = 0; };\n" "\n" "class MS : public M\n" "{ virtual void addController(C*) override {} };"); ASSERT_EQUALS("", errout.str()); // #6164 checkOldStylePointerCast("class Base {};\n" "class Derived: public Base {};\n" "void testCC() {\n" " std::vector v;\n" " v.push_back((Base*)new Derived);\n" "}"); ASSERT_EQUALS("[test.cpp:5]: (style) C-style pointer casting\n", errout.str()); // #7709 checkOldStylePointerCast("typedef struct S S;\n" "typedef struct S SS;\n" "typedef class C C;\n" "typedef long LONG;\n" "typedef long* LONGP;\n" "struct T {};\n" "typedef struct T TT;\n" "typedef struct T2 {} TT2;\n" "void f(int* i) {\n" " S* s = (S*)i;\n" " SS* ss = (SS*)i;\n" " struct S2* s2 = (struct S2*)i;\n" " C* c = (C*)i;\n" " class C2* c2 = (class C2*)i;\n" " long* l = (long*)i;\n" " LONG* l2 = (LONG*)i;\n" " LONGP l3 = (LONGP)i;\n" " TT* tt = (TT*)i;\n" " TT2* tt2 = (TT2*)i;\n" "}\n"); ASSERT_EQUALS("[test.cpp:10]: (style) C-style pointer casting\n" "[test.cpp:11]: (style) C-style pointer casting\n" "[test.cpp:12]: (style) C-style pointer casting\n" "[test.cpp:13]: (style) C-style pointer casting\n" "[test.cpp:14]: (style) C-style pointer casting\n" "[test.cpp:15]: (style) C-style pointer casting\n" "[test.cpp:16]: (style) C-style pointer casting\n" "[test.cpp:17]: (style) C-style pointer casting\n" "[test.cpp:18]: (style) C-style pointer casting\n" "[test.cpp:19]: (style) C-style pointer casting\n", errout.str()); // #8649 checkOldStylePointerCast("struct S {};\n" "void g(S*& s);\n" "void f(int i) {\n" " g((S*&)i);\n" " S*& r = (S*&)i;\n" "}\n"); ASSERT_EQUALS("[test.cpp:4]: (style) C-style pointer casting\n" "[test.cpp:5]: (style) C-style pointer casting\n", errout.str()); // #10823 checkOldStylePointerCast("void f(void* p) {\n" " auto h = reinterpret_cast(p);\n" "}\n"); ASSERT_EQUALS("", errout.str()); // #5210 checkOldStylePointerCast("void f(void* v1, void* v2) {\n" " T** p1 = (T**)v1;\n" " T*** p2 = (T***)v2;\n" "}\n"); ASSERT_EQUALS("[test.cpp:2]: (style) C-style pointer casting\n" "[test.cpp:3]: (style) C-style pointer casting\n", errout.str()); } #define checkInvalidPointerCast(...) checkInvalidPointerCast_(__FILE__, __LINE__, __VA_ARGS__) void checkInvalidPointerCast_(const char* file, int line, const char code[], bool portability = true, bool inconclusive = false) { // Clear the error buffer.. errout.str(""); Settings settings = settingsBuilder().severity(Severity::warning).severity(Severity::portability, portability).certainty(Certainty::inconclusive, inconclusive).build(); settings.platform.defaultSign = 's'; Preprocessor preprocessor(settings); // Tokenize.. Tokenizer tokenizer(&settings, this, &preprocessor); std::istringstream istr(code); ASSERT_LOC(tokenizer.tokenize(istr, "test.cpp"), file, line); CheckOther checkOtherCpp(&tokenizer, &settings, this); checkOtherCpp.invalidPointerCast(); } void invalidPointerCast() { checkInvalidPointerCast("void test() {\n" " float *f = new float[10];\n" " delete [] (double*)f;\n" " delete [] (long double const*)(new float[10]);\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (portability) Casting between float * and double * which have an incompatible binary data representation.\n" "[test.cpp:4]: (portability) Casting between float * and const long double * which have an incompatible binary data representation.\n", errout.str()); checkInvalidPointerCast("void test(const float* f) {\n" " double *d = (double*)f;\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (portability) Casting between const float * and double * which have an incompatible binary data representation.\n", errout.str()); checkInvalidPointerCast("void test(double* d1) {\n" " long double *ld = (long double*)d1;\n" " double *d2 = (double*)ld;\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (portability) Casting between double * and long double * which have an incompatible binary data representation.\n" "[test.cpp:3]: (portability) Casting between long double * and double * which have an incompatible binary data representation.\n", errout.str()); checkInvalidPointerCast("char* test(int* i) {\n" " long double *d = (long double*)(i);\n" " double *d = (double*)(i);\n" " float *f = reinterpret_cast(i);\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (portability) Casting between signed int * and long double * which have an incompatible binary data representation.\n" "[test.cpp:3]: (portability) Casting between signed int * and double * which have an incompatible binary data representation.\n" "[test.cpp:4]: (portability) Casting between signed int * and float * which have an incompatible binary data representation.\n", errout.str()); checkInvalidPointerCast("float* test(unsigned int* i) {\n" " return (float*)i;\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (portability) Casting between unsigned int * and float * which have an incompatible binary data representation.\n", errout.str()); checkInvalidPointerCast("float* test(unsigned int* i) {\n" " return (float*)i[0];\n" "}"); ASSERT_EQUALS("", errout.str()); checkInvalidPointerCast("float* test(double& d) {\n" " return (float*)&d;\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (portability) Casting between double * and float * which have an incompatible binary data representation.\n", errout.str()); checkInvalidPointerCast("void test(float* data) {\n" " f.write((char*)data,sizeof(float));\n" "}", true, false); ASSERT_EQUALS("", errout.str()); checkInvalidPointerCast("void test(float* data) {\n" " f.write((char*)data,sizeof(float));\n" "}", true, true); // #3639 ASSERT_EQUALS("[test.cpp:2]: (portability, inconclusive) Casting from float * to signed char * is not portable due to different binary data representations on different platforms.\n", errout.str()); checkInvalidPointerCast("long long* test(float* f) {\n" " return (long long*)f;\n" "}", false); ASSERT_EQUALS("", errout.str()); checkInvalidPointerCast("long long* test(float* f, char* c) {\n" " foo((long long*)f);\n" " return reinterpret_cast(c);\n" "}", true); ASSERT_EQUALS("[test.cpp:2]: (portability) Casting from float * to signed long long * is not portable due to different binary data representations on different platforms.\n", errout.str()); checkInvalidPointerCast("Q_DECLARE_METATYPE(int*)"); // #4135 - don't crash } void passedByValue() { check("void f(const std::string str) {}"); ASSERT_EQUALS("[test.cpp:1]: (performance) Function parameter 'str' should be passed by const reference.\n", errout.str()); check("void f(std::unique_ptr ptr) {}"); ASSERT_EQUALS("", errout.str()); check("void f(const std::shared_ptr ptr) {}"); ASSERT_EQUALS("", errout.str()); check("void f(const std::function ptr) {}"); ASSERT_EQUALS("", errout.str()); { check("void f(const std::pair x) {}"); ASSERT_EQUALS("", errout.str()); check("void f(const std::pair x) {}"); TODO_ASSERT_EQUALS("error", "", errout.str()); } check("void f(const std::string::size_type x) {}"); ASSERT_EQUALS("", errout.str()); check("class Foo;\nvoid f(const Foo foo) {}"); // Unknown class ASSERT_EQUALS("[test.cpp:2]: (performance, inconclusive) Function parameter 'foo' should be passed by const reference.\n", errout.str()); check("class Foo { std::vector v; };\nvoid f(const Foo foo) {}"); // Large class (STL member) ASSERT_EQUALS("[test.cpp:2]: (performance) Function parameter 'foo' should be passed by const reference.\n", errout.str()); check("class Foo { int i; };\nvoid f(const Foo foo) {}"); // Small class ASSERT_EQUALS("", errout.str()); check("class Foo { int i[6]; };\nvoid f(const Foo foo) {}"); // Large class (array) ASSERT_EQUALS("[test.cpp:2]: (performance) Function parameter 'foo' should be passed by const reference.\n", errout.str()); check("class Foo { std::string* s; };\nvoid f(const Foo foo) {}"); // Small class (pointer) ASSERT_EQUALS("", errout.str()); check("class Foo { static std::string s; };\nvoid f(const Foo foo) {}"); // Small class (static member) ASSERT_EQUALS("", errout.str()); check("class X { std::string s; }; class Foo : X { };\nvoid f(const Foo foo) {}"); // Large class (inherited) ASSERT_EQUALS("[test.cpp:2]: (performance) Function parameter 'foo' should be passed by const reference.\n", errout.str()); check("class X { std::string s; }; class Foo { X x; };\nvoid f(const Foo foo) {}"); // Large class (inherited) ASSERT_EQUALS("[test.cpp:2]: (performance) Function parameter 'foo' should be passed by const reference.\n", errout.str()); check("void f(const std::string &str) {}"); ASSERT_EQUALS("", errout.str()); // The idiomatic way of passing a std::string_view is by value check("void f(const std::string_view str) {}"); ASSERT_EQUALS("", errout.str()); check("void f(std::string_view str) {}"); ASSERT_EQUALS("", errout.str()); check("void f(const std::string_view &str) {}"); ASSERT_EQUALS("", errout.str()); check("void f(const std::vector v) {}"); ASSERT_EQUALS("[test.cpp:1]: (performance) Function parameter 'v' should be passed by const reference.\n", errout.str()); check("void f(const std::vector v) {}"); ASSERT_EQUALS("[test.cpp:1]: (performance) Function parameter 'v' should be passed by const reference.\n", errout.str()); check("void f(const std::vector::size_type s) {}"); ASSERT_EQUALS("", errout.str()); check("void f(const std::vector &v) {}"); ASSERT_EQUALS("", errout.str()); check("void f(const std::map &v) {}"); ASSERT_EQUALS("", errout.str()); check("void f(const std::map v) {}"); ASSERT_EQUALS("[test.cpp:1]: (performance) Function parameter 'v' should be passed by const reference.\n", errout.str()); check("void f(const std::map v) {}"); ASSERT_EQUALS("[test.cpp:1]: (performance) Function parameter 'v' should be passed by const reference.\n", errout.str()); check("void f(const std::map v) {}"); ASSERT_EQUALS("[test.cpp:1]: (performance) Function parameter 'v' should be passed by const reference.\n", errout.str()); check("void f(const std::map v) {}"); ASSERT_EQUALS("[test.cpp:1]: (performance) Function parameter 'v' should be passed by const reference.\n", errout.str()); check("void f(const std::streamoff pos) {}"); ASSERT_EQUALS("", errout.str()); check("void f(std::initializer_list i) {}"); ASSERT_EQUALS("", errout.str()); // #5824 check("void log(const std::string& file, int line, const std::string& function, const std::string str, ...) {}"); ASSERT_EQUALS("", errout.str()); // #5534 check("struct float3 { };\n" "typedef float3 vec;\n" "class Plane {\n" " vec Refract(vec &vec) const;\n" " bool IntersectLinePlane(const vec &planeNormal);\n" "};"); ASSERT_EQUALS("", errout.str()); check("class X {\n" " virtual void func(const std::string str) {}\n" "};"); ASSERT_EQUALS("[test.cpp:2]: (performance) Function parameter 'str' should be passed by const reference.\n", errout.str()); check("enum X;\n" "void foo(X x1){}\n"); ASSERT_EQUALS("", errout.str()); check("enum X { a, b, c };\n" "void foo(X x2){}\n"); ASSERT_EQUALS("", errout.str()); check("enum X { a, b, c };\n" "enum X;" "void foo(X x3){}\n"); ASSERT_EQUALS("", errout.str()); check("enum X;\n" "enum X { a, b, c };" "void foo(X x4){}\n"); ASSERT_EQUALS("", errout.str()); check("union U {\n" " char* pc;\n" " short* ps;\n" " int* pi;\n" "};\n" "void f(U u) {}\n"); ASSERT_EQUALS("", errout.str()); check("struct S { char A[8][8]; };\n" "void f(S s) {}\n"); ASSERT_EQUALS("[test.cpp:2]: (performance) Function parameter 's' should be passed by const reference.\n", errout.str()); check("union U {\n" // don't crash " int a;\n" " decltype(nullptr) b;\n" "};\n" "int* f(U u) { return u.b; }\n"); ASSERT_EQUALS("", errout.str()); check("struct B { virtual int f(std::string s) = 0; };\n" // #11432 "struct D1 : B {\n" " int f(std::string s) override { s += 'a'; return s.size(); }\n" "}\n" "struct D2 : B {\n" " int f(std::string s) override { return s.size(); }\n" "}\n"); ASSERT_EQUALS("", errout.str()); check("int x(int);\n" "void f(std::vector v, int& j) {\n" " for (int i : v)\n" " j = i;\n" "}\n" "void fn(std::vector v) {\n" " for (int& i : v)\n" " i = x(i);\n" "}\n" "void g(std::vector v, int& j) {\n" " for (int i = 0; i < v.size(); ++i)\n" " j = v[i];\n" "}\n" "void gn(std::vector v) {\n" " for (int i = 0; i < v.size(); ++i)\n" " v[i] = x(i);\n" "}\n" "void h(std::vector> v, int& j) {\n" " for (int i = 0; i < v.size(); ++i)\n" " j = v[i][0];\n" "}\n" "void hn(std::vector> v) {\n" " for (int i = 0; i < v.size(); ++i)\n" " v[i][0] = x(i);\n" "}\n"); ASSERT_EQUALS("[test.cpp:2]: (performance) Function parameter 'v' should be passed by const reference.\n" "[test.cpp:10]: (performance) Function parameter 'v' should be passed by const reference.\n" "[test.cpp:18]: (performance) Function parameter 'v' should be passed by const reference.\n", errout.str()); Settings settings1 = settingsBuilder().platform(cppcheck::Platform::Type::Win64).build(); check("using ui64 = unsigned __int64;\n" "ui64 Test(ui64 one, ui64 two) { return one + two; }\n", /*filename*/ nullptr, /*inconclusive*/ true, /*runSimpleChecks*/ true, /*verbose*/ false, &settings1); ASSERT_EQUALS("", errout.str()); } void passedByValue_nonConst() { check("void f(std::string str) {}"); ASSERT_EQUALS("[test.cpp:1]: (performance) Function parameter 'str' should be passed by const reference.\n", errout.str()); check("void f(std::string str) {\n" " return str + x;\n" "}"); ASSERT_EQUALS("[test.cpp:1]: (performance) Function parameter 'str' should be passed by const reference.\n", errout.str()); check("void f(std::string str) {\n" " std::cout << str;\n" "}"); ASSERT_EQUALS("[test.cpp:1]: (performance) Function parameter 'str' should be passed by const reference.\n", errout.str()); check("void f(std::string str) {\n" " std::cin >> str;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(std::string str) {\n" " std::string s2 = str;\n" "}"); ASSERT_EQUALS("[test.cpp:1]: (performance) Function parameter 'str' should be passed by const reference.\n", errout.str()); check("void f(std::string str) {\n" " std::string& s2 = str;\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Variable 's2' can be declared as reference to const\n", errout.str()); check("void f(std::string str) {\n" " const std::string& s2 = str;\n" "}"); ASSERT_EQUALS("[test.cpp:1]: (performance) Function parameter 'str' should be passed by const reference.\n", errout.str()); check("void f(std::string str) {\n" " str = \"\";\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(std::string str) {\n" " foo(str);\n" // It could be that foo takes str as non-const-reference "}"); ASSERT_EQUALS("", errout.str()); check("void foo(const std::string& str);\n" "void f(std::string str) {\n" " foo(str);\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (performance) Function parameter 'str' should be passed by const reference.\n", errout.str()); check("void foo(std::string str);\n" "void f(std::string str) {\n" " foo(str);\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (performance) Function parameter 'str' should be passed by const reference.\n", errout.str()); check("void foo(std::string& str);\n" "void f(std::string str) {\n" " foo(str);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(std::string* str);\n" "void f(std::string str) {\n" " foo(&str);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(int& i1, const std::string& str, int& i2);\n" "void f(std::string str) {\n" " foo((a+b)*c, str, x);\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (performance) Function parameter 'str' should be passed by const reference.\n", errout.str()); check("std::string f(std::string str) {\n" " str += x;\n" " return str;\n" "}"); ASSERT_EQUALS("", errout.str()); check("class X {\n" " std::string s;\n" " void func() const;\n" "};\n" "Y f(X x) {\n" " x.func();\n" "}"); ASSERT_EQUALS("[test.cpp:5]: (performance) Function parameter 'x' should be passed by const reference.\n", errout.str()); check("class X {\n" " void func();\n" "};\n" "Y f(X x) {\n" " x.func();\n" "}"); ASSERT_EQUALS("", errout.str()); check("class X {\n" " void func(std::string str) {}\n" "};"); ASSERT_EQUALS("[test.cpp:2]: (performance) Function parameter 'str' should be passed by const reference.\n", errout.str()); check("class X {\n" " virtual void func(std::string str) {}\n" // Do not warn about virtual functions, if 'str' is not declared as const "};"); ASSERT_EQUALS("", errout.str()); check("class X {\n" " char a[1024];\n" "};\n" "class Y : X {\n" " char b;\n" "};\n" "void f(Y y) {\n" "}"); ASSERT_EQUALS("[test.cpp:7]: (performance) Function parameter 'y' should be passed by const reference.\n", errout.str()); check("class X {\n" " void* a;\n" " void* b;\n" "};\n" "class Y {\n" " void* a;\n" " void* b;\n" " char c;\n" "};\n" "void f(X x, Y y) {\n" "}"); ASSERT_EQUALS("[test.cpp:10]: (performance) Function parameter 'y' should be passed by const reference.\n", errout.str()); { // 8-byte data should be passed by const reference on 32-bit platform but not on 64-bit platform const char code[] = "class X {\n" " uint64_t a;\n" " uint64_t b;\n" "};\n" "void f(X x) {}"; Settings s32 = settingsBuilder(_settings).platform(cppcheck::Platform::Type::Unix32).build(); check(code, &s32); ASSERT_EQUALS("[test.cpp:5]: (performance) Function parameter 'x' should be passed by const reference.\n", errout.str()); Settings s64 = settingsBuilder(_settings).platform(cppcheck::Platform::Type::Unix64).build(); check(code, &s64); ASSERT_EQUALS("", errout.str()); } check("Writer* getWriter();\n" "\n" "void foo(Buffer& buffer) {\n" " getWriter()->operator<<(buffer);\n" "}"); ASSERT_EQUALS("", errout.str()); } void passedByValue_externC() { check("struct X { int a[5]; }; void f(X v) { }"); ASSERT_EQUALS("[test.cpp:1]: (performance) Function parameter 'v' should be passed by const reference.\n", errout.str()); check("extern \"C\" { struct X { int a[5]; }; void f(X v) { } }"); ASSERT_EQUALS("", errout.str()); check("struct X { int a[5]; }; extern \"C\" void f(X v) { }"); ASSERT_EQUALS("", errout.str()); check("struct X { int a[5]; }; void f(const X v);"); ASSERT_EQUALS("[test.cpp:1]: (performance) Function parameter 'v' should be passed by const reference.\n", errout.str()); check("extern \"C\" { struct X { int a[5]; }; void f(const X v); }"); ASSERT_EQUALS("", errout.str()); check("struct X { int a[5]; }; extern \"C\" void f(const X v) { }"); ASSERT_EQUALS("", errout.str()); } void constVariable() { check("int f(std::vector x) {\n" " int& i = x[0];\n" " return i;\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Variable 'i' can be declared as reference to const\n", errout.str()); check("int f(std::vector& x) {\n" " return x[0];\n" "}"); ASSERT_EQUALS("[test.cpp:1]: (style) Parameter 'x' can be declared as reference to const\n", errout.str()); check("int f(std::vector x) {\n" " const int& i = x[0];\n" " return i;\n" "}"); ASSERT_EQUALS("[test.cpp:1]: (performance) Function parameter 'x' should be passed by const reference.\n", errout.str()); check("int f(std::vector x) {\n" " static int& i = x[0];\n" " return i;\n" "}"); ASSERT_EQUALS("", errout.str()); check("int f(std::vector x) {\n" " int& i = x[0];\n" " i++;\n" " return i;\n" "}"); ASSERT_EQUALS("", errout.str()); check("int& f(std::vector& x) {\n" " x.push_back(1);\n" " int& i = x[0];\n" " return i;\n" "}"); ASSERT_EQUALS("", errout.str()); check("int f(const std::vector& x) {\n" " return x[0];\n" "}"); ASSERT_EQUALS("", errout.str()); check("int& f(std::vector& x) {\n" " return x[0];\n" "}"); ASSERT_EQUALS("", errout.str()); check("const int& f(std::vector& x) {\n" " return x[0];\n" "}"); ASSERT_EQUALS("[test.cpp:1]: (style) Parameter 'x' can be declared as reference to const\n", errout.str()); check("int f(std::vector& x) {\n" " x[0]++;\n" " return x[0];\n" "}"); ASSERT_EQUALS("", errout.str()); check("struct A { int a; };\n" "A f(std::vector& x) {\n" " x[0].a = 1;\n" " return x[0];\n" "}"); ASSERT_EQUALS("", errout.str()); check("struct A { int a(); };\n" "A f(std::vector& x) {\n" " x[0].a();\n" " return x[0];\n" "}"); ASSERT_EQUALS("", errout.str()); check("int g(int& x);\n" "int f(std::vector& x) {\n" " g(x[0]);\n" " return x[0];\n" "}"); ASSERT_EQUALS("", errout.str()); check("template\n" "T f(T& x) {\n" " return x[0];\n" "}"); ASSERT_EQUALS("", errout.str()); check("template\n" "T f(T&& x) {\n" " return x[0];\n" "}"); ASSERT_EQUALS("", errout.str()); check("template\n" "T f(T& x) {\n" " return x[0];\n" "}\n" "void h() { std::vector v; h(v); }"); ASSERT_EQUALS("", errout.str()); check("int f(int& x) {\n" " return std::move(x);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(std::ostream& os) {\n" " os << \"Hello\";\n" "}"); ASSERT_EQUALS("", errout.str()); check("void g(int*);\n" "void f(int& x) {\n" " g(&x);\n" "}"); ASSERT_EQUALS("", errout.str()); check("struct A { A(int*); };\n" "A f(int& x) {\n" " return A(&x);\n" "}"); ASSERT_EQUALS("", errout.str()); check("struct A { A(int*); };\n" "A f(int& x) {\n" " return A{&x};\n" "}"); ASSERT_EQUALS("", errout.str()); // Perhaps unused variable should be checked as well. check("void f(int& x, int& y) {\n" " y++;\n" "}"); ASSERT_EQUALS("", errout.str()); check("struct A {\n" " explicit A(int& y) : x(&y) {}\n" " int * x = nullptr;\n" "};"); ASSERT_EQUALS("", errout.str()); check("struct A {\n" " std::vector v;\n" " void swap(A& a) {\n" " v.swap(a.v);\n" " }\n" "};"); ASSERT_EQUALS("", errout.str()); check("struct A {\n" " template\n" " void f();\n" " template\n" " void f() const;\n" "};\n" "void g(A& a) {\n" " a.f();\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(std::vector& v) {\n" " for(auto&& x:v)\n" " x = 1;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(std::vector& v) {\n" " for(auto x:v)\n" " x = 1;\n" "}"); ASSERT_EQUALS("[test.cpp:1]: (style) Parameter 'v' can be declared as reference to const\n", errout.str()); check("void f(std::vector& v) {\n" " for(auto& x:v) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Variable 'x' can be declared as reference to const\n", errout.str()); check("void f(std::vector& v) {\n" // #10980 " for (int& i : v)\n" " if (i == 0) {}\n" " for (const int& i : v)\n" " if (i == 0) {}\n" " for (auto& i : v)\n" " if (i == 0) {}\n" " for (const auto& i : v)\n" " if (i == 0) {}\n" " v.clear();\n" "}\n"); ASSERT_EQUALS("[test.cpp:2]: (style) Variable 'i' can be declared as reference to const\n" "[test.cpp:6]: (style) Variable 'i' can be declared as reference to const\n", errout.str()); check("void f(std::vector& v) {\n" " for(const auto& x:v) {}\n" "}"); ASSERT_EQUALS("[test.cpp:1]: (style) Parameter 'v' can be declared as reference to const\n", errout.str()); check("void f(int& i) {\n" " int& j = i;\n" " j++;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(std::vector& v) {\n" " int& i = v[0];\n" " i++;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(std::map >& m, unsigned int i) {\n" " std::map& members = m[i];\n" " members.clear();\n" "}"); ASSERT_EQUALS("", errout.str()); check("struct A {\n" " int& x;\n" " A(int& y) : x(y)\n" " {}\n" "};"); ASSERT_EQUALS("", errout.str()); check("struct A {\n" " A(int& x);\n" "};\n" "struct B : A {\n" " B(int& x) : A(x)\n" " {}\n" "};"); ASSERT_EQUALS("", errout.str()); check("void f(bool b, int& x, int& y) {\n" " auto& z = x;\n" " auto& w = b ? y : z;\n" " w = 1;\n" "}"); ASSERT_EQUALS("", errout.str()); check("struct S {\n" " int i;\n" "};\n" "int& f(S& s) {\n" " return s.i;\n" "}"); ASSERT_EQUALS("", errout.str()); check("int* f(std::list& x, unsigned int y) {\n" " for (int& m : x) {\n" " if (m == y)\n" " return &m;\n" " }\n" " return nullptr;\n" "}"); ASSERT_EQUALS("", errout.str()); check("int& f(std::list& x, int& y) {\n" " for (int& m : x) {\n" " if (m == y)\n" " return m;\n" " }\n" " return y;\n" "}"); ASSERT_EQUALS("", errout.str()); check("bool from_string(int& t, const std::string& s) {\n" " std::istringstream iss(s);\n" " return !(iss >> t).fail();\n" "}\n"); ASSERT_EQUALS("", errout.str()); // #9710 check("class a {\n" " void operator()(int& i) const {\n" " i++;\n" " }\n" "};\n" "void f(int& i) {\n" " a()(i);\n" "}\n"); ASSERT_EQUALS("", errout.str()); check("class a {\n" " void operator()(int& i) const {\n" " i++;\n" " }\n" "};\n" "void f(int& i) {\n" " a x;\n" " x(i);\n" "}\n"); ASSERT_EQUALS("", errout.str()); check("class a {\n" " void operator()(const int& i) const;\n" "};\n" "void f(int& i) {\n" " a x;\n" " x(i);\n" "}\n"); ASSERT_EQUALS("[test.cpp:4]: (style) Parameter 'i' can be declared as reference to const\n", errout.str()); //cast or assignment to a non-const reference should prevent the warning check("struct T { void dostuff() const {}};\n" "void a(T& x) {\n" " x.dostuff();\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Parameter 'x' can be declared as reference to const\n", errout.str()); check("struct T : public U { void dostuff() const {}};\n" "void a(T& x) {\n" " x.dostuff();\n" " const T& z = x;\n" //Make sure we find all assignments " T& y = x\n" " y.mutate();\n" //to avoid warnings that y can be const "}"); ASSERT_EQUALS("", errout.str()); check("struct T : public U { void dostuff() const {}};\n" "void a(T& x) {\n" " x.dostuff();\n" " const U& y = x\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Parameter 'x' can be declared as reference to const\n", errout.str()); check("struct T : public U { void dostuff() const {}};\n" "void a(T& x) {\n" " x.dostuff();\n" " U& y = x\n" " y.mutate();\n" //to avoid warnings that y can be const "}"); ASSERT_EQUALS("", errout.str()); check("struct T : public U { void dostuff() const {}};\n" "void a(T& x) {\n" " x.dostuff();\n" " my::type& y = x\n" //we don't know if y is const or not " y.mutate();\n" //to avoid warnings that y can be const "}"); ASSERT_EQUALS("", errout.str()); check("struct T : public U { void dostuff() const {}};\n" "void a(T& x) {\n" " x.dostuff();\n" " const U& y = static_cast(x)\n" " y.mutate();\n" //to avoid warnings that y can be const "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Parameter 'x' can be declared as reference to const\n", errout.str()); check("struct T : public U { void dostuff() const {}};\n" "void a(T& x) {\n" " x.dostuff();\n" " U& y = static_cast(x)\n" " y.mutate();\n" //to avoid warnings that y can be const "}"); ASSERT_EQUALS("", errout.str()); check("struct T : public U { void dostuff() const {}};\n" "void a(T& x) {\n" " x.dostuff();\n" " const U& y = dynamic_cast(x)\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Parameter 'x' can be declared as reference to const\n", errout.str()); check( "struct T : public U { void dostuff() const {}};\n" "void a(T& x) {\n" " x.dostuff();\n" " const U& y = dynamic_cast(x)\n" "}" ); ASSERT_EQUALS("[test.cpp:2]: (style) Parameter 'x' can be declared as reference to const\n", errout.str()); check("struct T : public U { void dostuff() const {}};\n" "void a(T& x) {\n" " x.dostuff();\n" " const U& y = dynamic_cast(x)\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Parameter 'x' can be declared as reference to const\n", errout.str()); check("struct T : public U { void dostuff() const {}};\n" "void a(T& x) {\n" " x.dostuff();\n" " U& y = dynamic_cast(x)\n" " y.mutate();\n" //to avoid warnings that y can be const "}"); ASSERT_EQUALS("", errout.str()); check("struct T : public U { void dostuff() const {}};\n" "void a(T& x) {\n" " x.dostuff();\n" " const U& y = dynamic_cast(x)\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Parameter 'x' can be declared as reference to const\n", errout.str()); check("struct T : public U { void dostuff() const {}};\n" "void a(T& x) {\n" " x.dostuff();\n" " U& y = dynamic_cast(x)\n" " y.mutate();\n" //to avoid warnings that y can be const "}"); ASSERT_EQUALS("", errout.str()); check("struct T : public U { void dostuff() const {}};\n" "void a(T& x) {\n" " x.dostuff();\n" " U* y = dynamic_cast(&x)\n" " y->mutate();\n" //to avoid warnings that y can be const "}"); ASSERT_EQUALS("", errout.str()); check("struct T : public U { void dostuff() const {}};\n" "void a(T& x) {\n" " x.dostuff();\n" " const U * y = dynamic_cast(&x)\n" " y->mutate();\n" //to avoid warnings that y can be const "}"); TODO_ASSERT_EQUALS("can be const", errout.str(), ""); //Currently taking the address is treated as a non-const operation when it should depend on what we do with it check("struct T : public U { void dostuff() const {}};\n" "void a(T& x) {\n" " x.dostuff();\n" " U const * y = dynamic_cast(&x)\n" " y->mutate();\n" //to avoid warnings that y can be const "}"); TODO_ASSERT_EQUALS("can be const", errout.str(), ""); //Currently taking the address is treated as a non-const operation when it should depend on what we do with it check("struct T : public U { void dostuff() const {}};\n" "void a(T& x) {\n" " x.dostuff();\n" " U * const y = dynamic_cast(&x)\n" " y->mutate();\n" //to avoid warnings that y can be const "}"); ASSERT_EQUALS("", errout.str()); check("struct T : public U { void dostuff() const {}};\n" "void a(T& x) {\n" " x.dostuff();\n" " const U const * const * const * const y = dynamic_cast(&x)\n" " y->mutate();\n" //to avoid warnings that y can be const "}"); TODO_ASSERT_EQUALS("can be const", errout.str(), ""); //Currently taking the address is treated as a non-const operation when it should depend on what we do with it check("struct T : public U { void dostuff() const {}};\n" "void a(T& x) {\n" " x.dostuff();\n" " const U const * const * * const y = dynamic_cast(&x)\n" " y->mutate();\n" //to avoid warnings that y can be const "}"); ASSERT_EQUALS("", errout.str()); check("struct T : public U { void dostuff() const {}};\n" "void a(T& x) {\n" " x.dostuff();\n" " my::fancy const * * const y = dynamic_cast const * * const>(&x)\n" " y->mutate();\n" //to avoid warnings that y can be const "}"); ASSERT_EQUALS("", errout.str()); check("struct T : public U { void dostuff() const {}};\n" "void a(T& x) {\n" " x.dostuff();\n" " my::fancy const * const * const y = dynamic_cast const * const * const>(&x)\n" " y->mutate();\n" //to avoid warnings that y can be const "}"); ASSERT_EQUALS("", errout.str()); check("struct T : public U { void dostuff() const {}};\n" "void a(T& x) {\n" " x.dostuff();\n" " const U& y = (const U&)(x)\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Parameter 'x' can be declared as reference to const\n", errout.str()); check("struct T : public U { void dostuff() const {}};\n" "void a(T& x) {\n" " x.dostuff();\n" " U& y = (U&)(x)\n" " y.mutate();\n" //to avoid warnings that y can be const "}"); ASSERT_EQUALS("", errout.str()); check("struct T : public U { void dostuff() const {}};\n" "void a(T& x) {\n" " x.dostuff();\n" " const U& y = (typename const U&)(x)\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Parameter 'x' can be declared as reference to const\n", errout.str()); check("struct T : public U { void dostuff() const {}};\n" "void a(T& x) {\n" " x.dostuff();\n" " U& y = (typename U&)(x)\n" " y.mutate();\n" //to avoid warnings that y can be const "}"); ASSERT_EQUALS("", errout.str()); check("struct T : public U { void dostuff() const {}};\n" "void a(T& x) {\n" " x.dostuff();\n" " U* y = (U*)(&x)\n" " y->mutate();\n" //to avoid warnings that y can be const "}"); ASSERT_EQUALS("[test.cpp:4]: (style) C-style pointer casting\n", errout.str()); check("struct C { void f() const; };\n" // #9875 - crash "\n" "void foo(C& x) {\n" " x.f();\n" " foo( static_cast(0) );\n" "}"); ASSERT_EQUALS("", errout.str()); check("class a {\n" " void foo(const int& i) const;\n" " void operator()(int& i) const;\n" "};\n" "void f(int& i) {\n" " a()(i);\n" "}\n"); ASSERT_EQUALS("", errout.str()); check("class a {\n" " void operator()(const int& i) const;\n" "};\n" "void f(int& i) {\n" " a()(i);\n" "}\n"); ASSERT_EQUALS("[test.cpp:4]: (style) Parameter 'i' can be declared as reference to const\n", errout.str()); // #9767 check("void fct1(MyClass& object) {\n" " fct2([&](void){}, object);\n" "}\n" "bool fct2(std::function lambdaExpression, MyClass& object) {\n" " object.modify();\n" "}\n"); ASSERT_EQUALS("", errout.str()); // #9778 check("struct A {};\n" "struct B : A {};\n" "B& f(A& x) {\n" " return static_cast(x);\n" "}\n"); ASSERT_EQUALS("", errout.str()); // #10002 check("using A = int*;\n" "void f(const A& x) {\n" " ++(*x);\n" "}\n"); ASSERT_EQUALS("", errout.str()); // #10086 check("struct V {\n" " V& get(typename std::vector::size_type i) {\n" " std::vector& arr = v;\n" " return arr[i];\n" " }\n" " std::vector v;\n" "};\n"); ASSERT_EQUALS("", errout.str()); check("void e();\n" "void g(void);\n" "void h(void);\n" "void ah(void);\n" "void ai(void);\n" "void j(void);\n" "void e(void);\n" "void k(void);\n" "void l(void);\n" "void m(void);\n" "void n(void);\n" "void o(void);\n" "void q(void);\n" "void r(void);\n" "void t(void);\n" "void u(void);\n" "void v(void);\n" "void w(void);\n" "void z(void);\n" "void aj(void);\n" "void am(void);\n" "void g(void);\n" "void h(void);\n" "void ah(void);\n" "void an(void);\n" "void e(void);\n" "void k(void);\n" "void ao(wchar_t *d);\n" "void ah(void);\n" "void e(void);\n" "void an(void);\n" "void e(void);\n" "void k(void);\n" "void g(void);\n" "void ah(void);\n" "void an(void);\n" "void e(void);\n" "void e(void);\n" "void e(void);\n" "void k(void);\n" "void g(void);\n" "void ah(void);\n" "void an(void);\n" "void e(void);\n" "void e(void);\n" "void k(void);\n" "void g(void);\n" "void h(void);\n" "void ah(void);\n" "void an(void);\n" "void e(void);\n" "void k(void);\n" "void e(void);\n" "void g(void);\n" "void ah(void);\n" "void k(void);\n" "void an(void);\n" "void e(void);\n" "void e(void);\n" "void e(void);\n" "void k(void);\n" "void g(void);\n" "void h(void);\n" "void ah(void);\n" "void k(void);\n" "void an(void);\n" "void k(void);\n" "void e(void);\n" "void g(void);\n" "void ah(void);\n" "void e(void);\n" "void k(void);\n" "void g(void);\n" "void h(void);\n" "void ah(void);\n" "void an(void);\n" "void an(void);\n" "void k(void);\n" "void e(void);\n" "void e(void);\n" "void e(void);\n" "void g(void);\n" "void k(void);\n" "void g(void);\n" "void h(void);\n" "void ah(void);\n" "void an(void);\n" "void k(void);\n" "void k(void);\n" "void e(void);\n" "void g(void);\n" "void g(void);\n" "void ah(void);\n" "void an(void);\n" "void e(void);\n" "void k(void);\n" "void e(void);\n" "void ap(wchar_t *c, int d);\n" "void ah(void);\n" "void an(void);\n" "void g(void);\n" "void h(void);\n" "void ah(void);\n" "void aq(char *b, size_t d, char *c, int a);\n" "void ar(char *b, size_t d, char *c, va_list a);\n" "void k(void);\n" "void g(void);\n" "void g(void);\n" "void h(void);\n" "void ah(void);\n" "void an(void);\n" "void k(void);\n" "void k(void);\n" "void e(void);\n" "void g(void);\n" "void g(void);\n" "void as(std::string s);\n" "void at(std::ifstream &f);\n" "void au(std::istream &f);\n" "void av(std::string &aa, std::wstring &ab);\n" "void aw(bool b, double x, double y);\n" "void ax(int i);\n" "void ay(std::string c, std::wstring a);\n" "void az(const std::locale &ac);\n" "void an();\n" "void ba(std::ifstream &f);\n" "void bb(std::istream &f) {\n" "f.read(NULL, 0);\n" "}\n" "void h(void) {\n" "struct tm *tm = 0;\n" "(void)std::asctime(tm);\n" "(void)std::asctime(0);\n" "}\n" "void bc(size_t ae) {\n" "wchar_t *ad = 0, *af = 0;\n" "struct tm *ag = 0;\n" "(void)std::wcsftime(ad, ae, af, ag);\n" "(void)std::wcsftime(0, ae, 0, 0);\n" "}\n" "void k(void) {}\n" "void bd(void);\n" "void be(void);\n" "void bf(int b);\n" "void e(void);\n" "void e(void);\n" "void bg(wchar_t *p);\n" "void bh(const std::list &ak, const std::list &al);\n" "void ah();\n" "void an();\n" "void h();"); ASSERT_EQUALS("", errout.str()); check("class C\n" "{\n" "public:\n" " explicit C(int&);\n" "};\n" "\n" "class D\n" "{\n" "public:\n" " explicit D(int&);\n" "\n" "private:\n" " C c;\n" "};\n" "\n" "D::D(int& i)\n" " : c(i)\n" "{\n" "}"); ASSERT_EQUALS("", errout.str()); check("class C\n" "{\n" "public:\n" " explicit C(int&);\n" "};\n" "\n" "class D\n" "{\n" "public:\n" " explicit D(int&) noexcept;\n" "\n" "private:\n" " C c;\n" "};\n" "\n" "D::D(int& i) noexcept\n" " : c(i)\n" "{}"); ASSERT_EQUALS("", errout.str()); check("class C\n" "{\n" "public:\n" " explicit C(const int&);\n" "};\n" "\n" "class D\n" "{\n" "public:\n" " explicit D(int&);\n" "\n" "private:\n" " C c;\n" "};\n" "\n" "D::D(int& i)\n" " : c(i)\n" "{\n" "}"); TODO_ASSERT_EQUALS("[test.cpp:16]: (style) Parameter 'i' can be declared as reference to const\n", "", errout.str()); check("class C\n" "{\n" "public:\n" " explicit C(int);\n" "};\n" "\n" "class D\n" "{\n" "public:\n" " explicit D(int&);\n" "\n" "private:\n" " C c;\n" "};\n" "\n" "D::D(int& i)\n" " : c(i)\n" "{\n" "}"); TODO_ASSERT_EQUALS("[test.cpp:16]: (style) Parameter 'i' can be declared as reference to const\n", "", errout.str()); check("class C\n" "{\n" "public:\n" " explicit C(int, int);\n" "};\n" "\n" "class D\n" "{\n" "public:\n" " explicit D(int&);\n" "\n" "private:\n" " C c;\n" "};\n" "\n" "D::D(int& i)\n" " : c(0, i)\n" "{\n" "}"); TODO_ASSERT_EQUALS("[test.cpp:16]: (style) Parameter 'i' can be declared as reference to const\n", "", errout.str()); check("void f(std::map> &map) {\n" // #10266 " for (auto &[slave, panels] : map)\n" " panels.erase(it);\n" "}"); ASSERT_EQUALS("", errout.str()); check("struct S { void f(); int i; };\n" "void call_f(S& s) { (s.*(&S::f))(); }\n"); ASSERT_EQUALS("", errout.str()); check("struct S { int a[1]; };\n" "void f(S& s) { int* p = s.a; *p = 0; }\n"); ASSERT_EQUALS("", errout.str()); check("struct Foo {\n" // #9910 " int* p{};\n" " int* get() { return p; }\n" " const int* get() const { return p; }\n" "};\n" "struct Bar {\n" " int j{};\n" " void f(Foo& foo) const { int* q = foo.get(); *q = j; }\n" "};\n"); ASSERT_EQUALS("", errout.str()); check("struct S {\n" // #10679 " void g(long L, const C*& PC) const;\n" " void g(long L, C*& PC);\n" "};\n" "void f(S& s) {\n" " C* PC{};\n" " s.g(0, PC);\n" "};\n"); ASSERT_EQUALS("", errout.str()); // #10785 check("template \n" "struct d {\n" " T& g(C& c, T C::*f) { return c.*f; }\n" "};\n"); ASSERT_EQUALS("", errout.str()); check("void f(std::map& m) {\n" " std::cout << m[0] << std::endl;\n" "};\n"); ASSERT_EQUALS("", errout.str()); check("void f(std::vector>& v) {\n" // #11607 " for (auto& m : v)\n" " std::cout << m[0];\n" "}\n"); ASSERT_EQUALS("", errout.str()); check("struct S { int i; };\n" // #11473 "void f(std::vector>&m, int*& p) {\n" " auto& a = m[0];\n" " for (auto& s : a) {\n" " p = &s.i;\n" " return;\n" " }\n" "}\n"); ASSERT_EQUALS("", errout.str()); check("int& g(int* p, int& r) {\n" // #11625 " if (p)\n" " return *p;\n" " return r;\n" "}\n"); ASSERT_EQUALS("", errout.str()); check("template void f(std::vector& d, const std::vector& s) {\n" // #11632 " for (const auto& e : s) {\n" " T* newE = new T(*e);\n" " d.push_back(newE);\n" " }\n" "}\n"); ASSERT_EQUALS("", errout.str()); check("void f(std::array& a) {\n" " if (a[0]) {}\n" "}\n" "void g(std::array& a) {\n" " a.fill(0);\n" "}\n"); ASSERT_EQUALS("[test.cpp:1]: (style) Parameter 'a' can be declared as const array\n", errout.str()); // #11682 check("struct b {\n" " void mutate();\n" "};\n" "struct c {\n" " const b& get() const;\n" " b get();\n" "};\n" "struct d {\n" " void f(c& e) const {\n" " e.get().mutate();\n" " }\n" "};\n"); ASSERT_EQUALS("", errout.str()); check("struct A {\n" // #11225 " A();\n" " virtual ~A();\n" "};\n" "struct B : A {};\n" "void f(A* a) {\n" " const B* b = dynamic_cast(a);\n" "}\n" "void g(A* a) {\n" " const B* b = (const B*)a;\n" "}\n"); ASSERT_EQUALS("[test.cpp:10]: (style) C-style pointer casting\n" "[test.cpp:6]: (style) Parameter 'a' can be declared as pointer to const\n" "[test.cpp:9]: (style) Parameter 'a' can be declared as pointer to const\n", errout.str()); } void constParameterCallback() { check("int callback(std::vector& x) { return x[0]; }\n" "void f() { dostuff(callback); }"); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:1]: (style) Parameter 'x' can be declared as reference to const. However it seems that 'callback' is a callback function, if 'x' is declared with const you might also need to cast function pointer(s).\n", errout.str()); // #9906 check("class EventEngine : public IEventEngine {\n" "public:\n" " EventEngine();\n" "\n" "private:\n" " void signalEvent(ev::sig& signal, int revents);\n" "};\n" "\n" "EventEngine::EventEngine() {\n" " mSigWatcher.set(this);\n" "}\n" "\n" "void EventEngine::signalEvent(ev::sig& signal, int revents) {\n" " switch (signal.signum) {}\n" "}"); ASSERT_EQUALS("[test.cpp:10] -> [test.cpp:13]: (style) Parameter 'signal' can be declared as reference to const. However it seems that 'signalEvent' is a callback function, if 'signal' is declared with const you might also need to cast function pointer(s).\n", errout.str()); } void constPointer() { check("void foo(int *p) { return *p; }"); ASSERT_EQUALS("[test.cpp:1]: (style) Parameter 'p' can be declared as pointer to const\n", errout.str()); check("void foo(int *p) { x = *p; }"); ASSERT_EQUALS("[test.cpp:1]: (style) Parameter 'p' can be declared as pointer to const\n", errout.str()); check("void foo(int *p) { int &ref = *p; ref = 12; }"); ASSERT_EQUALS("", errout.str()); check("void foo(int *p) { x = *p + 10; }"); ASSERT_EQUALS("[test.cpp:1]: (style) Parameter 'p' can be declared as pointer to const\n", errout.str()); check("void foo(int *p) { return p[10]; }"); ASSERT_EQUALS("[test.cpp:1]: (style) Parameter 'p' can be declared as pointer to const\n", errout.str()); check("void foo(int *p) { int &ref = p[0]; ref = 12; }"); ASSERT_EQUALS("", errout.str()); check("void foo(int *p) { x[*p] = 12; }"); ASSERT_EQUALS("[test.cpp:1]: (style) Parameter 'p' can be declared as pointer to const\n", errout.str()); check("void foo(int *p) { if (p) {} }"); ASSERT_EQUALS("[test.cpp:1]: (style) Parameter 'p' can be declared as pointer to const\n", errout.str()); check("void foo(int *p) { if (p || x) {} }"); ASSERT_EQUALS("[test.cpp:1]: (style) Parameter 'p' can be declared as pointer to const\n", errout.str()); check("void foo(int *p) { if (p == 0) {} }"); ASSERT_EQUALS("[test.cpp:1]: (style) Parameter 'p' can be declared as pointer to const\n", errout.str()); check("void foo(int *p) { if (!p) {} }"); ASSERT_EQUALS("[test.cpp:1]: (style) Parameter 'p' can be declared as pointer to const\n", errout.str()); check("void foo(int *p) { if (*p > 123) {} }"); ASSERT_EQUALS("[test.cpp:1]: (style) Parameter 'p' can be declared as pointer to const\n", errout.str()); check("void foo(int *p) { return *p + 1; }"); ASSERT_EQUALS("[test.cpp:1]: (style) Parameter 'p' can be declared as pointer to const\n", errout.str()); check("void foo(int *p) { return *p > 1; }"); ASSERT_EQUALS("[test.cpp:1]: (style) Parameter 'p' can be declared as pointer to const\n", errout.str()); check("void foo(const int* c) { if (c == 0) {}; }"); ASSERT_EQUALS("", errout.str()); check("struct a { void b(); };\n" "struct c {\n" " a* d;\n" " a& g() { return *d; }\n" "};\n"); ASSERT_EQUALS("", errout.str()); check("struct a { void b(); };\n" "struct c { a* d; };\n" "void e(c);\n"); ASSERT_EQUALS("", errout.str()); check("struct V {\n" " V& get(typename std::vector::size_type i, std::vector* arr) {\n" " return arr->at(i);\n" " }\n" "};\n"); ASSERT_EQUALS("", errout.str()); check("struct A {};\n" "struct B : A {};\n" "B* f(A* x) {\n" " return static_cast(x);\n" "}\n"); ASSERT_EQUALS("", errout.str()); check("int f(std::vector* x) {\n" " int& i = (*x)[0];\n" " i++;\n" " return i;\n" "}"); ASSERT_EQUALS("", errout.str()); check("struct A { int a; };\n" "A f(std::vector* x) {\n" " x->front().a = 1;\n" " return x->front();\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(std::vector* v) {\n" " for(auto&& x:*v)\n" " x = 1;\n" "}"); ASSERT_EQUALS("", errout.str()); check("struct A {\n" " int* x;\n" " A(int* y) : x(y)\n" " {}\n" "};"); ASSERT_EQUALS("", errout.str()); check("void f(bool b, int* x, int* y) {\n" " int* z = x;\n" " int* w = b ? y : z;\n" " *w = 1;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(bool b, int* x, int* y) {\n" " int& z = *x;\n" " int& w = b ? *y : z;\n" " w = 1;\n" "}"); ASSERT_EQUALS("", errout.str()); check("class Base { virtual void dostuff(int *p) = 0; };\n" // #10397 "class Derived: public Base { int x; void dostuff(int *p) override { x = *p; } };"); ASSERT_EQUALS("", errout.str()); check("struct Data { char buf[128]; };\n" // #10483 "void encrypt(Data& data) {\n" " const char a[] = \"asfasd\";\n" " memcpy(data.buf, &a, sizeof(a));\n" "}"); ASSERT_EQUALS("", errout.str()); // #10547 check("void foo(std::istream &istr) {\n" " unsigned char x[2];\n" " istr >> x[0];\n" "}"); ASSERT_EQUALS("", errout.str()); // #10744 check("S& f() {\n" " static S* p = new S();\n" " return *p;\n" "}\n"); ASSERT_EQUALS("", errout.str()); check("int f() {\n" " static int i[1] = {};\n" " return i[0];\n" "}\n"); ASSERT_EQUALS("[test.cpp:2]: (style) Variable 'i' can be declared as const array\n", errout.str()); check("int f() {\n" " static int i[] = { 0 };\n" " int j = i[0] + 1;\n" " return j;\n" "}\n"); ASSERT_EQUALS("[test.cpp:2]: (style) Variable 'i' can be declared as const array\n", errout.str()); // #10471 check("void f(std::array const& i) {\n" " if (i[0] == 0) {}\n" "}\n"); ASSERT_EQUALS("", errout.str()); // #10466 check("typedef void* HWND;\n" "void f(const std::vector&v) {\n" " for (const auto* h : v)\n" " if (h) {}\n" " for (const auto& h : v)\n" " if (h) {}\n" "}\n"); ASSERT_EQUALS("[test.cpp:5]: (style) Variable 'h' can be declared as pointer to const\n", errout.str()); check("void f(const std::vector& v) {\n" " for (const auto& p : v)\n" " if (p == nullptr) {}\n" " for (const auto* p : v)\n" " if (p == nullptr) {}\n" "}\n"); ASSERT_EQUALS("[test.cpp:2]: (style) Variable 'p' can be declared as pointer to const\n", errout.str()); check("void f(std::vector& v) {\n" " for (const auto& p : v)\n" " if (p == nullptr) {}\n" " for (const auto* p : v)\n" " if (p == nullptr) {}\n" " for (const int* const& p : v)\n" " if (p == nullptr) {}\n" " for (const int* p : v)\n" " if (p == nullptr) {}\n" "}\n"); ASSERT_EQUALS("[test.cpp:1]: (style) Parameter 'v' can be declared as reference to const\n" "[test.cpp:2]: (style) Variable 'p' can be declared as pointer to const\n", errout.str()); check("void f(std::vector& v) {\n" " for (const auto& p : v)\n" " if (p == nullptr) {}\n" " for (const auto* p : v)\n" " if (p == nullptr) {}\n" "}\n"); ASSERT_EQUALS("[test.cpp:1]: (style) Parameter 'v' can be declared as reference to const\n", errout.str()); check("void f(const std::vector& v) {\n" " for (const auto& p : v)\n" " if (p == nullptr) {}\n" " for (const auto* p : v)\n" " if (p == nullptr) {}\n" "}\n"); ASSERT_EQUALS("", errout.str()); check("void f(const int* const p) {\n" " if (p == nullptr) {}\n" "}\n"); ASSERT_EQUALS("", errout.str()); check("void g(int*);\n" "void f(int* const* pp) {\n" " int* p = pp[0];\n" " g(p);\n" "}\n"); ASSERT_EQUALS("", errout.str()); check("template \n" "struct S {\n" " static bool f(const T& t) { return t != nullptr; }\n" "};\n" "S s;\n"); ASSERT_EQUALS("", errout.str()); check("void f(int i) {\n" " const char *tmp;\n" " char* a[] = { \"a\", \"aa\" };\n" " static char* b[] = { \"b\", \"bb\" };\n" " tmp = a[i];\n" " printf(\"%s\", tmp);\n" " tmp = b[i];\n" " printf(\"%s\", tmp);\n" "}\n"); ASSERT_EQUALS("[test.cpp:3]: (style) Variable 'a' can be declared as const array\n" "[test.cpp:4]: (style) Variable 'b' can be declared as const array\n", errout.str()); check("typedef void* HWND;\n" // #11084 "void f(const HWND h) {\n" " if (h == nullptr) {}\n" "}\n"); ASSERT_EQUALS("", errout.str()); check("using HWND = void*;\n" "void f(const HWND h) {\n" " if (h == nullptr) {}\n" "}\n"); ASSERT_EQUALS("", errout.str()); check("typedef int A;\n" "void f(A* x) {\n" " if (x == nullptr) {}\n" "}\n"); ASSERT_EQUALS("[test.cpp:2]: (style) Parameter 'x' can be declared as pointer to const\n", errout.str()); check("using A = int;\n" "void f(A* x) {\n" " if (x == nullptr) {}\n" "}\n"); ASSERT_EQUALS("[test.cpp:2]: (style) Parameter 'x' can be declared as pointer to const\n", errout.str()); check("struct S { void v(); };\n" // #11095 "void f(S* s) {\n" " (s - 1)->v();\n" "}\n"); ASSERT_EQUALS("", errout.str()); check("void f(std::vector& v) {\n" // #11085 " for (int* p : v) {\n" " if (p) {}\n" " }\n" " for (auto* p : v) {\n" " if (p) {}\n" " }\n" " v.clear();\n" "}\n"); ASSERT_EQUALS("[test.cpp:2]: (style) Variable 'p' can be declared as pointer to const\n" "[test.cpp:5]: (style) Variable 'p' can be declared as pointer to const\n", errout.str()); check("void f() {\n" " char a[1][1];\n" " char* b[1];\n" " b[0] = a[0];\n" " **b = 0;\n" "}\n"); ASSERT_EQUALS("", errout.str()); check("ptrdiff_t f(int *p0, int *p1) {\n" // #11148 " return p0 - p1;\n" "}\n"); ASSERT_EQUALS("[test.cpp:1]: (style) Parameter 'p0' can be declared as pointer to const\n" "[test.cpp:1]: (style) Parameter 'p1' can be declared as pointer to const\n", errout.str()); check("void f() {\n" " std::array a{}, b{};\n" " const std::array& r = a;\n" " if (r == b) {}\n" "}\n"); ASSERT_EQUALS("", errout.str()); check("struct S {};\n" // #11599 "void g(S);\n" "void h(const S&);\n" "void h(int, int, const S&);\n" "void i(S&);\n" "void j(const S*);\n" "void j(int, int, const S*);\n" "void f1(S* s) {\n" " g(*s);\n" "}\n" "void f2(S* s) {\n" " h(*s);\n" "}\n" "void f3(S* s) {\n" " h(1, 2, *s);\n" "}\n" "void f4(S* s) {\n" " i(*s);\n" "}\n" "void f5(S& s) {\n" " j(&s);\n" "}\n" "void f6(S& s) {\n" " j(1, 2, &s);\n" "}\n"); ASSERT_EQUALS("[test.cpp:20]: (style) Parameter 's' can be declared as reference to const\n" "[test.cpp:23]: (style) Parameter 's' can be declared as reference to const\n" "[test.cpp:8]: (style) Parameter 's' can be declared as pointer to const\n" "[test.cpp:11]: (style) Parameter 's' can be declared as pointer to const\n" "[test.cpp:14]: (style) Parameter 's' can be declared as pointer to const\n", errout.str()); check("void g(int, const int*);\n" "void h(const int*);\n" "void f(int* p) {\n" " g(1, p);\n" " h(p);\n" "}\n"); ASSERT_EQUALS("[test.cpp:3]: (style) Parameter 'p' can be declared as pointer to const\n", errout.str()); check("void f(int, const int*);\n" "void f(int i, int* p) {\n" " f(i, const_cast(p));\n" "}\n"); ASSERT_EQUALS("", errout.str()); check("struct S { int a; };\n" "void f(std::vector& v, int b) {\n" " size_t n = v.size();\n" " for (size_t i = 0; i < n; i++) {\n" " S& s = v[i];\n" " if (!(b & s.a))\n" " continue;\n" " }\n" "}\n"); ASSERT_EQUALS("[test.cpp:5]: (style) Variable 's' can be declared as reference to const\n", errout.str()); // don't crash check("void f(int& i) {\n" " new (&i) int();\n" "}\n"); ASSERT_EQUALS("", errout.str()); // don't crash check("void f(int& i) {\n" " int& r = i;\n" " if (!&r) {}\n" "}\n"); ASSERT_EQUALS("[test.cpp:2]: (style) Variable 'r' can be declared as reference to const\n", errout.str()); // don't crash check("class C;\n" // #11646 "void g(const C* const p);\n" "void f(C* c) {\n" " g(c);\n" "}\n"); ASSERT_EQUALS("[test.cpp:3]: (style) Parameter 'c' can be declared as pointer to const\n", errout.str()); check("typedef void (*cb_t)(int*);\n" // #11674 "void cb(int* p) {\n" " if (*p) {}\n" "}\n" "void g(cb_t);\n" "void f() {\n" " g(cb);\n" "}\n"); ASSERT_EQUALS("[test.cpp:7] -> [test.cpp:2]: (style) Parameter 'p' can be declared as pointer to const. " "However it seems that 'cb' is a callback function, if 'p' is declared with const you might also need to cast function pointer(s).\n", errout.str()); check("typedef void (*cb_t)(int*);\n" "void cb(int* p) {\n" " if (*p) {}\n" "}\n" "void g(cb_t);\n" "void f() {\n" " g(::cb);\n" "}\n"); ASSERT_EQUALS("[test.cpp:7] -> [test.cpp:2]: (style) Parameter 'p' can be declared as pointer to const. " "However it seems that 'cb' is a callback function, if 'p' is declared with const you might also need to cast function pointer(s).\n", errout.str()); check("void f1(std::vector* p) {\n" // #11681 " if (p->empty()) {}\n" // warn "}\n" "void f2(std::vector* p) {\n" " p->resize(0);\n" "}\n" "struct S {\n" " void h1() const;\n" " void h2();\n" " int i;\n" "};\n" "void k(int&);\n" "void g1(S* s) {\n" " s->h1();\n" // warn "}\n" "void g1(S* s) {\n" " s->h2();\n" "}\n" "void g1(S* s) {\n" " if (s->i) {}\n" // warn "}\n" "void g2(S* s) {\n" " s->i = 0;\n" "}\n" "void g3(S* s) {\n" " k(s->i);\n" "}\n"); ASSERT_EQUALS("[test.cpp:1]: (style) Parameter 'p' can be declared as pointer to const\n" "[test.cpp:13]: (style) Parameter 's' can be declared as pointer to const\n" "[test.cpp:19]: (style) Parameter 's' can be declared as pointer to const\n", errout.str()); check("struct S {\n" // #11573 " const char* g() const {\n" " return m;\n" " }\n" " const char* m;\n" "};\n" "struct T { std::vector v; };\n" "void f(T* t, const char* n) {\n" " for (const auto* p : t->v)\n" " if (strcmp(p->g(), n) == 0) {}\n" "}\n"); ASSERT_EQUALS("[test.cpp:8]: (style) Parameter 't' can be declared as pointer to const\n", errout.str()); check("void f(int*& p, int* q) {\n" " p = q;\n" "}\n"); ASSERT_EQUALS("", errout.str()); } void switchRedundantAssignmentTest() { check("void foo()\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " y = 2;\n" " case 3:\n" " y = 3;\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("[test.cpp:7] -> [test.cpp:9]: (style) Variable 'y' is reassigned a value before the old one has been used. 'break;' missing?\n", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " {\n" " y = 2;\n" " }\n" " case 3:\n" " y = 3;\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("[test.cpp:8] -> [test.cpp:11]: (style) Variable 'y' is reassigned a value before the old one has been used. 'break;' missing?\n", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " y = 2;\n" " case 3:\n" " if (x)\n" " {\n" " y = 3;\n" " }\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " {\n" " y = 2;\n" " if (z)\n" " printf(\"%d\", y);\n" " }\n" " case 3:\n" " y = 3;\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo()\n" "{\n" " int x = a;\n" " int y = 1;\n" " switch (x)\n" " {\n" " case 2:\n" " x = 2;\n" " case 3:\n" " y = 3;\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " switch (x)\n" " {\n" " case 2:\n" " y = 2;\n" " break;\n" " case 3:\n" " y = 3;\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " while(xyz()) {\n" " switch (x)\n" " {\n" " case 2:\n" " y = 2;\n" " continue;\n" " case 3:\n" " y = 3;\n" " }\n" " bar(y);\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " while(xyz()) {\n" " switch (x)\n" " {\n" " case 2:\n" " y = 2;\n" " throw e;\n" " case 3:\n" " y = 3;\n" " }\n" " bar(y);\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " switch (x)\n" " {\n" " case 2:\n" " y = 2;\n" " printf(\"%d\", y);\n" " case 3:\n" " y = 3;\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " switch (x)\n" " {\n" " case 2:\n" " y = 2;\n" " bar();\n" " case 3:\n" " y = 3;\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("[test.cpp:7] -> [test.cpp:10]: (style) Variable 'y' is reassigned a value before the old one has been used. 'break;' missing?\n", errout.str()); check("void bar() {}\n" // bar isn't noreturn "void foo()\n" "{\n" " int y = 1;\n" " switch (x)\n" " {\n" " case 2:\n" " y = 2;\n" " bar();\n" " case 3:\n" " y = 3;\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("[test.cpp:8] -> [test.cpp:11]: (style) Variable 'y' is reassigned a value before the old one has been used. 'break;' missing?\n", errout.str()); check("void foo(int a) {\n" " char str[10];\n" " switch (a)\n" " {\n" " case 2:\n" " strcpy(str, \"a'\");\n" " case 3:\n" " strcpy(str, \"b'\");\n" " }\n" "}", nullptr, false, false); TODO_ASSERT_EQUALS("[test.cpp:6] -> [test.cpp:8]: (style) Buffer 'str' is being written before its old content has been used. 'break;' missing?\n", "", errout.str()); check("void foo(int a) {\n" " char str[10];\n" " switch (a)\n" " {\n" " case 2:\n" " strncpy(str, \"a'\");\n" " case 3:\n" " strncpy(str, \"b'\");\n" " }\n" "}"); TODO_ASSERT_EQUALS("[test.cpp:6] -> [test.cpp:8]: (style) Buffer 'str' is being written before its old content has been used. 'break;' missing?\n", "", errout.str()); check("void foo(int a) {\n" " char str[10];\n" " int z = 0;\n" " switch (a)\n" " {\n" " case 2:\n" " strcpy(str, \"a'\");\n" " z++;\n" " case 3:\n" " strcpy(str, \"b'\");\n" " z++;\n" " }\n" "}", nullptr, false, false); TODO_ASSERT_EQUALS("[test.cpp:7] -> [test.cpp:10]: (style) Buffer 'str' is being written before its old content has been used. 'break;' missing?\n", "", errout.str()); check("void foo(int a) {\n" " char str[10];\n" " switch (a)\n" " {\n" " case 2:\n" " strcpy(str, \"a'\");\n" " break;\n" " case 3:\n" " strcpy(str, \"b'\");\n" " break;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(int a) {\n" " char str[10];\n" " switch (a)\n" " {\n" " case 2:\n" " strcpy(str, \"a'\");\n" " printf(str);\n" " case 3:\n" " strcpy(str, \"b'\");\n" " }\n" "}", nullptr, false, false); ASSERT_EQUALS("", errout.str()); // Ticket #5158 "segmentation fault (valid code)" check("typedef struct ct_data_s {\n" " union {\n" " char freq;\n" " } fc;\n" "} ct_data;\n" "typedef struct internal_state {\n" " struct ct_data_s dyn_ltree[10];\n" "} deflate_state;\n" "void f(deflate_state *s) {\n" " s->dyn_ltree[0].fc.freq++;\n" "}\n", nullptr, false, false); ASSERT_EQUALS("", errout.str()); // Ticket #6132 "crash: daca: kvirc CheckOther::checkRedundantAssignment()" check("void HttpFileTransfer :: transferTerminated ( bool bSuccess@1 ) {\n" "if ( m_szCompletionCallback . isNull ( ) ) {\n" "KVS_TRIGGER_EVENT ( KviEvent_OnHTTPGetTerminated , out ? out : ( g_pApp . activeConsole ( ) ) , & vParams )\n" "} else {\n" "KviKvsScript :: run ( m_szCompletionCallback , out ? out : ( g_pApp . activeConsole ( ) ) , & vParams ) ;\n" "}\n" "}\n", nullptr, false, true); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " int x;\n" " switch (state) {\n" " case 1: x = 3; goto a;\n" " case 1: x = 6; goto a;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); } void switchRedundantOperationTest() { check("void foo()\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " ++y;\n" " case 3:\n" " y = 3;\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("[test.cpp:7] -> [test.cpp:9]: (style) Variable 'y' is reassigned a value before the old one has been used. 'break;' missing?\n", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " {\n" " ++y;\n" " }\n" " case 3:\n" " y = 3;\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("[test.cpp:8] -> [test.cpp:11]: (style) Variable 'y' is reassigned a value before the old one has been used. 'break;' missing?\n", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " (void)y;\n" " case 3:\n" " ++y;\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " ++y;\n" " case 3:\n" " ++y;\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " --y;\n" " case 3:\n" " y = 3;\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("[test.cpp:7] -> [test.cpp:9]: (style) Variable 'y' is reassigned a value before the old one has been used. 'break;' missing?\n", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " {\n" " --y;\n" " }\n" " case 3:\n" " y = 3;\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("[test.cpp:8] -> [test.cpp:11]: (style) Variable 'y' is reassigned a value before the old one has been used. 'break;' missing?\n", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " (void)y;\n" " case 3:\n" " --y;\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " --y;\n" " case 3:\n" " --y;\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " y++;\n" " case 3:\n" " y = 3;\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("[test.cpp:7] -> [test.cpp:9]: (style) Variable 'y' is reassigned a value before the old one has been used. 'break;' missing?\n", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " {\n" " y++;\n" " }\n" " case 3:\n" " y = 3;\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("[test.cpp:8] -> [test.cpp:11]: (style) Variable 'y' is reassigned a value before the old one has been used. 'break;' missing?\n", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " y = 2;\n" " case 3:\n" " y++;\n" " }\n" " bar(y);\n" "}", nullptr, false, false); ASSERT_EQUALS("", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " y++;\n" " case 3:\n" " y++;\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " y--;\n" " case 3:\n" " y = 3;\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("[test.cpp:7] -> [test.cpp:9]: (style) Variable 'y' is reassigned a value before the old one has been used. 'break;' missing?\n", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " {\n" " y--;\n" " }\n" " case 3:\n" " y = 3;\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("[test.cpp:8] -> [test.cpp:11]: (style) Variable 'y' is reassigned a value before the old one has been used. 'break;' missing?\n", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " y = 2;\n" " case 3:\n" " y--;\n" " }\n" " bar(y);\n" "}", nullptr, false, false); ASSERT_EQUALS("", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " y--;\n" " case 3:\n" " y--;\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " y++;\n" " case 3:\n" " if (x)\n" " {\n" " y = 3;\n" " }\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " {\n" " y++;\n" " if (y)\n" " printf(\"%d\", y);\n" " }\n" " case 3:\n" " y = 3;\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo()\n" "{\n" " int x = a;\n" " int y = 1;\n" " switch (x)\n" " {\n" " case 2:\n" " x++;\n" " case 3:\n" " y++;\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " switch (x)\n" " {\n" " case 2:\n" " y++;\n" " break;\n" " case 3:\n" " y = 3;\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " while(xyz()) {\n" " switch (x)\n" " {\n" " case 2:\n" " y++;\n" " continue;\n" " case 3:\n" " y = 3;\n" " }\n" " bar(y);\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " while(xyz()) {\n" " switch (x)\n" " {\n" " case 2:\n" " y++;\n" " throw e;\n" " case 3:\n" " y = 3;\n" " }\n" " bar(y);\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " switch (x)\n" " {\n" " case 2:\n" " y++;\n" " printf(\"%d\", y);\n" " case 3:\n" " y = 3;\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo()\n" "{\n" " int y = 1;\n" " switch (x)\n" " {\n" " case 2:\n" " y++;\n" " bar();\n" " case 3:\n" " y = 3;\n" " }\n" " bar(y);\n" "}"); ASSERT_EQUALS("[test.cpp:7] -> [test.cpp:10]: (style) Variable 'y' is reassigned a value before the old one has been used. 'break;' missing?\n", errout.str()); check("bool f() {\n" " bool ret = false;\n" " switch (switchCond) {\n" " case 1:\n" " ret = true;\n" " break;\n" " case 31:\n" " ret = true;\n" " break;\n" " case 54:\n" " ret = true;\n" " break;\n" " };\n" " ret = true;\n" " return ret;\n" "}"); ASSERT_EQUALS("[test.cpp:5] -> [test.cpp:14]: (style) Variable 'ret' is reassigned a value before the old one has been used.\n" "[test.cpp:8] -> [test.cpp:14]: (style) Variable 'ret' is reassigned a value before the old one has been used.\n" "[test.cpp:11] -> [test.cpp:14]: (style) Variable 'ret' is reassigned a value before the old one has been used.\n", errout.str()); } void switchRedundantBitwiseOperationTest() { check("void foo(int a)\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " y |= 3;\n" " case 3:\n" " y |= 3;\n" " break;\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:7]: (style) Redundant bitwise operation on 'y' in 'switch' statement. 'break;' missing?\n", errout.str()); check("void foo(int a)\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " y = y | 3;\n" " case 3:\n" " y = y | 3;\n" " break;\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:7]: (style) Redundant bitwise operation on 'y' in 'switch' statement. 'break;' missing?\n", errout.str()); check("void foo(int a)\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " y |= 3;\n" " default:\n" " y |= 3;\n" " break;\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:7]: (style) Redundant bitwise operation on 'y' in 'switch' statement. 'break;' missing?\n", errout.str()); check("void foo(int a)\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " y |= 3;\n" " default:\n" " if (z)\n" " y |= 3;\n" " break;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(int a)\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " y |= z;\n" " z++\n" " default:\n" " y |= z;\n" " break;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(int a)\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " y |= 3;\n" " bar(y);\n" " case 3:\n" " y |= 3;\n" " break;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(int a)\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " y |= 3;\n" " y = 4;\n" " case 3:\n" " y |= 3;\n" " break;\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:7] -> [test.cpp:8]: (style) Variable 'y' is reassigned a value before the old one has been used.\n", errout.str()); check("void foo(int a)\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " y &= 3;\n" " case 3:\n" " y &= 3;\n" " break;\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:7]: (style) Redundant bitwise operation on 'y' in 'switch' statement. 'break;' missing?\n", errout.str()); check("void foo(int a)\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " y |= 3;\n" " break;\n" " case 3:\n" " y |= 3;\n" " break;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(int a)\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " y ^= 3;\n" " case 3:\n" " y ^= 3;\n" " break;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(int a)\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " y |= 2;\n" " case 3:\n" " y |= 3;\n" " break;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(int a)\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " y &= 2;\n" " case 3:\n" " y &= 3;\n" " break;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(int a)\n" "{\n" " int y = 1;\n" " switch (a)\n" " {\n" " case 2:\n" " y |= 2;\n" " case 3:\n" " y &= 2;\n" " break;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); } void unreachableCode() { check("void foo(int a) {\n" " while(1) {\n" " if (a++ >= 100) {\n" " break;\n" " continue;\n" " }\n" " }\n" "}", nullptr, false, false); ASSERT_EQUALS("[test.cpp:5]: (style) Consecutive return, break, continue, goto or throw statements are unnecessary.\n", errout.str()); check("int foo(int a) {\n" " return 0;\n" " return(a-1);\n" "}", nullptr, false, false); ASSERT_EQUALS("[test.cpp:3]: (style) Consecutive return, break, continue, goto or throw statements are unnecessary.\n", errout.str()); check("int foo(int a) {\n" " A:" " return(0);\n" " goto A;\n" "}", nullptr, false, false); ASSERT_EQUALS("[test.cpp:3]: (style) Consecutive return, break, continue, goto or throw statements are unnecessary.\n", errout.str()); Settings settings; settings.library.setnoreturn("exit", true); settings.library.functions["exit"].argumentChecks[1] = Library::ArgumentChecks(); check("void foo() {\n" " exit(0);\n" " break;\n" "}", nullptr, false, false, false, &settings); ASSERT_EQUALS("[test.cpp:3]: (style) Consecutive return, break, continue, goto or throw statements are unnecessary.\n", errout.str()); check("class NeonSession {\n" " void exit();\n" "};\n" "void NeonSession::exit()\n" "{\n" " SAL_INFO(\"ucb.ucp.webdav\", \"neon commands cannot be aborted\");\n" "}", nullptr, false, false, false, &settings); ASSERT_EQUALS("", errout.str()); check("void NeonSession::exit()\n" "{\n" " SAL_INFO(\"ucb.ucp.webdav\", \"neon commands cannot be aborted\");\n" "}", nullptr, false, false, false, &settings); ASSERT_EQUALS("", errout.str()); check("void foo() { xResAccess->exit(); }", nullptr, false, false, false, &settings); ASSERT_EQUALS("", errout.str()); check("void foo(int a)\n" "{\n" " switch(a) {\n" " case 0:\n" " printf(\"case 0\");\n" " break;\n" " break;\n" " case 1:\n" " c++;\n" " break;\n" " }\n" "}", nullptr, false, false); ASSERT_EQUALS("[test.cpp:7]: (style) Consecutive return, break, continue, goto or throw statements are unnecessary.\n", errout.str()); check("void foo(int a)\n" "{\n" " switch(a) {\n" " case 0:\n" " printf(\"case 0\");\n" " break;\n" " case 1:\n" " c++;\n" " break;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(int a)\n" "{\n" " while(true) {\n" " if (a++ >= 100) {\n" " break;\n" " break;\n" " }\n" " }\n" "}", nullptr, false, false); ASSERT_EQUALS("[test.cpp:6]: (style) Consecutive return, break, continue, goto or throw statements are unnecessary.\n", errout.str()); check("void foo(int a)\n" "{\n" " while(true) {\n" " if (a++ >= 100) {\n" " continue;\n" " continue;\n" " }\n" " a+=2;\n" " }\n" "}", nullptr, false, false); ASSERT_EQUALS("[test.cpp:6]: (style) Consecutive return, break, continue, goto or throw statements are unnecessary.\n", errout.str()); check("void foo(int a)\n" "{\n" " while(true) {\n" " if (a++ >= 100) {\n" " continue;\n" " }\n" " a+=2;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("int foo() {\n" " throw 0;\n" " return 1;\n" "}", nullptr, false, false); ASSERT_EQUALS("[test.cpp:3]: (style) Consecutive return, break, continue, goto or throw statements are unnecessary.\n", errout.str()); check("void foo() {\n" " throw 0;\n" " return;\n" "}", nullptr, false, false); ASSERT_EQUALS("[test.cpp:3]: (style) Consecutive return, break, continue, goto or throw statements are unnecessary.\n", errout.str()); check("int foo() {\n" " throw = 0;\n" " return 1;\n" "}", "test.c", false, false); ASSERT_EQUALS("", errout.str()); check("int foo() {\n" " return 0;\n" " return 1;\n" "}", nullptr, false, false, false); ASSERT_EQUALS("[test.cpp:3]: (style) Consecutive return, break, continue, goto or throw statements are unnecessary.\n", errout.str()); check("int foo() {\n" " return 0;\n" " foo();\n" "}", nullptr, false, false); ASSERT_EQUALS("[test.cpp:3]: (style) Statements following 'return' will never be executed.\n", errout.str()); check("int foo(int unused) {\n" " return 0;\n" " (void)unused;\n" "}", nullptr, false, false); ASSERT_EQUALS("", errout.str()); check("int foo(int unused1, int unused2) {\n" " return 0;\n" " (void)unused1;\n" " (void)unused2;\n" "}", nullptr, false, false); ASSERT_EQUALS("", errout.str()); check("int foo(int unused1, int unused2) {\n" " return 0;\n" " (void)unused1;\n" " (void)unused2;\n" " foo();\n" "}", nullptr, false, false); ASSERT_EQUALS("[test.cpp:5]: (style) Statements following 'return' will never be executed.\n", errout.str()); check("int foo() {\n" " if(bar)\n" " return 0;\n" " return 124;\n" "}"); ASSERT_EQUALS("", errout.str()); check("int foo() {\n" " while(bar) {\n" " return 0;\n" " return 0;\n" " return 0;\n" " return 0;\n" " }\n" " return 124;\n" "}", nullptr, false, false); ASSERT_EQUALS("[test.cpp:4]: (style) Consecutive return, break, continue, goto or throw statements are unnecessary.\n", errout.str()); check("void foo() {\n" " while(bar) {\n" " return;\n" " break;\n" " }\n" "}", nullptr, false, false); ASSERT_EQUALS("[test.cpp:4]: (style) Consecutive return, break, continue, goto or throw statements are unnecessary.\n", errout.str()); // #5707 check("extern int i,j;\n" "int foo() {\n" " switch(i) {\n" " default: j=1; break;\n" " }\n" " return 0;\n" " j=2;\n" "}", nullptr, false, false); ASSERT_EQUALS("[test.cpp:7]: (style) Statements following 'return' will never be executed.\n", errout.str()); check("int foo() {\n" " return 0;\n" " label:\n" " throw 0;\n" "}", nullptr, false, false); ASSERT_EQUALS("[test.cpp:3]: (style) Label 'label' is not used.\n", errout.str()); check("struct A {\n" " virtual void foo (P & Val) throw ();\n" " virtual void foo1 (P & Val) throw ();\n" "}"); ASSERT_EQUALS("", errout.str()); check("int foo() {\n" " goto label;\n" " while (true) {\n" " bar();\n" " label:\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); // #3457 check("int foo() {\n" " goto label;\n" " do {\n" " bar();\n" " label:\n" " } while (true);\n" "}"); ASSERT_EQUALS("", errout.str()); // #3457 check("int foo() {\n" " goto label;\n" " for (;;) {\n" " bar();\n" " label:\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); // #3457 // #3383. TODO: Use preprocessor check("int foo() {\n" "\n" // #ifdef A " return 0;\n" "\n" // #endif " return 1;\n" "}", nullptr, false, false); ASSERT_EQUALS("", errout.str()); check("int foo() {\n" "\n" // #ifdef A " return 0;\n" "\n" // #endif " return 1;\n" "}", nullptr, true, false); ASSERT_EQUALS("[test.cpp:5]: (style, inconclusive) Consecutive return, break, continue, goto or throw statements are unnecessary.\n", errout.str()); // #4711 lambda functions check("int f() {\n" " return g([](int x){(void)x+1; return x;});\n" "}", nullptr, false, false); ASSERT_EQUALS("", errout.str()); // #4756 check("template <>\n" "inline uint16_t htobe(uint16_t value) {\n" " return ( __extension__ ({\n" " register unsigned short int __v, __x = (unsigned short int) (value);\n" " if (__builtin_constant_p (__x))\n" " __v = ((unsigned short int) ((((__x) >> 8) & 0xff) | (((__x) & 0xff) << 8)));\n" " else\n" " __asm__ (\"rorw $8, %w0\" : \"=r\" (__v) : \"0\" (__x) : \"cc\");\n" " (void)__v;\n" " }));\n" "}", nullptr, false, false); ASSERT_EQUALS("", errout.str()); // #6008 check("static std::function< int ( int, int ) > GetFunctor() {\n" " return [](int a_, int b_) -> int {\n" " int sum = a_ + b_;\n" " return sum;\n" " };\n" "}", nullptr, false, false); ASSERT_EQUALS("", errout.str()); // #5789 check("struct per_state_info {\n" " uint64_t enter, exit;\n" " uint64_t events;\n" " per_state_info() : enter(0), exit(0), events(0) {}\n" "};", nullptr, false, false); ASSERT_EQUALS("", errout.str()); // #6664 check("void foo() {\n" " (beat < 100) ? (void)0 : exit(0);\n" " bar();\n" "}", nullptr, false, false, false, &settings); ASSERT_EQUALS("", errout.str()); check("void foo() {\n" " (beat < 100) ? exit(0) : (void)0;\n" " bar();\n" "}", nullptr, false, false, false, &settings); ASSERT_EQUALS("", errout.str()); // #8261 // TODO Do not throw AST validation exception TODO_ASSERT_THROW(check("void foo() {\n" " (beat < 100) ? (void)0 : throw(0);\n" " bar();\n" "}", nullptr, false, false, false, &settings), InternalError); //ASSERT_EQUALS("", errout.str()); check("int foo() {\n" " exit(0);\n" " return 1;\n" // <- clarify for tools that function does not continue.. "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " enum : uint8_t { A, B } var = A;\n" "}\n"); ASSERT_EQUALS("", errout.str()); checkP("#define INB(x) __extension__ ({ u_int tmp = (x); inb(tmp); })\n" // #4739 "static unsigned char cmos_hal_read(unsigned index) {\n" " unsigned short port_0, port_1;\n" " assert(!verify_cmos_byte_index(index));\n" " if (index < 128) {\n" " port_0 = 0x70;\n" " port_1 = 0x71;\n" " }\n" " else {\n" " port_0 = 0x72;\n" " port_1 = 0x73;\n" " }\n" " OUTB(index, port_0);\n" " return INB(port_1);\n" "}\n", "test.c"); ASSERT_EQUALS("", errout.str()); check("[[noreturn]] void n();\n" "void f() {\n" " n();\n" " g();\n" "}\n"); ASSERT_EQUALS("[test.cpp:4]: (style) Statements following noreturn function 'n()' will never be executed.\n", errout.str()); check("void f() {\n" " exit(1);\n" " g();\n" "}\n"); ASSERT_EQUALS("[test.cpp:3]: (style) Statements following noreturn function 'exit()' will never be executed.\n", errout.str()); check("void f() {\n" " do {\n" " break;\n" " g();\n" " } while (0);\n" "}\n"); ASSERT_EQUALS("[test.cpp:4]: (style) Statements following 'break' will never be executed.\n", errout.str()); } void redundantContinue() { check("void f() {\n" // #11195 " for (int i = 0; i < 10; ++i) {\n" " printf(\"i = %d\\n\", i);\n" " continue;\n" " }\n" "}\n"); ASSERT_EQUALS("[test.cpp:4]: (style) 'continue' is redundant since it is the last statement in a loop.\n", errout.str()); check("void f() {\n" " int i = 0;" " do {\n" " ++i;\n" " printf(\"i = %d\\n\", i);\n" " continue;\n" " } while (i < 10);\n" "}\n"); ASSERT_EQUALS("[test.cpp:5]: (style) 'continue' is redundant since it is the last statement in a loop.\n", errout.str()); } void suspiciousCase() { check("void foo() {\n" " switch(a) {\n" " case A&&B:\n" " foo();\n" " case (A||B):\n" " foo();\n" " case A||B:\n" " foo();\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (warning, inconclusive) Found suspicious case label in switch(). Operator '&&' probably doesn't work as intended.\n" "[test.cpp:5]: (warning, inconclusive) Found suspicious case label in switch(). Operator '||' probably doesn't work as intended.\n" "[test.cpp:7]: (warning, inconclusive) Found suspicious case label in switch(). Operator '||' probably doesn't work as intended.\n", errout.str()); check("void foo() {\n" " switch(a) {\n" " case 1:\n" " a=A&&B;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); // TODO Do not throw AST validation exception TODO_ASSERT_THROW(check("void foo() {\n" " switch(a) {\n" " case A&&B?B:A:\n" " foo();\n" " }\n" "}"), InternalError); //ASSERT_EQUALS("", errout.str()); } void suspiciousEqualityComparison() { check("void foo(int c) {\n" " if (x) c == 0;\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (warning, inconclusive) Found suspicious equality comparison. Did you intend to assign a value instead?\n", errout.str()); check("void foo(const int* c) {\n" " if (x) *c == 0;\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (warning, inconclusive) Found suspicious equality comparison. Did you intend to assign a value instead?\n", errout.str()); check("void foo(int c) {\n" " if (c == 1) {\n" " c = 0;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(int c) {\n" " c == 1;\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (warning, inconclusive) Found suspicious equality comparison. Did you intend to assign a value instead?\n", errout.str()); check("void foo(int c) {\n" " for (int i = 0; i == 10; i ++) {\n" " a ++;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(int c) {\n" " for (i == 0; i < 10; i ++) {\n" " c ++;\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (warning, inconclusive) Found suspicious equality comparison. Did you intend to assign a value instead?\n", errout.str()); check("void foo(int c) {\n" " for (i == 1; i < 10; i ++) {\n" " c ++;\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (warning, inconclusive) Found suspicious equality comparison. Did you intend to assign a value instead?\n", errout.str()); check("void foo(int c) {\n" " for (i == 2; i < 10; i ++) {\n" " c ++;\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (warning, inconclusive) Found suspicious equality comparison. Did you intend to assign a value instead?\n", errout.str()); check("void foo(int c) {\n" " for (int i = 0; i < 10; i == c) {\n" " c ++;\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (warning, inconclusive) Found suspicious equality comparison. Did you intend to assign a value instead?\n", errout.str()); check("void foo(int c) {\n" " for (; running == 1;) {\n" " c ++;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(int c) {\n" " printf(\"%i\", ({x==0;}));\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(int arg) {\n" " printf(\"%i\", ({int x = do_something(); x == 0;}));\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(int x) {\n" " printf(\"%i\", ({x == 0; x > 0 ? 10 : 20}));\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (warning, inconclusive) Found suspicious equality comparison. Did you intend to assign a value instead?\n", errout.str()); check("void foo(int x) {\n" " for (const Token* end = tok->link(); tok != end; tok = (tok == end) ? end : tok->next()) {\n" " x++;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(int x) {\n" " for (int i = (x == 0) ? 0 : 5; i < 10; i ++) {\n" " x++;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(int x) {\n" " for (int i = 0; i < 10; i += (x == 5) ? 1 : 2) {\n" " x++;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); } void suspiciousUnaryPlusMinus() { // #8004 check("int g() { return 1; }\n" "void f() {\n" " +g();\n" " -g();\n" "}\n"); ASSERT_EQUALS("[test.cpp:3]: (warning, inconclusive) Found suspicious operator '+', result is not used.\n" "[test.cpp:4]: (warning, inconclusive) Found suspicious operator '-', result is not used.\n", errout.str()); check("void f(int i) {\n" " +i;\n" " -i;\n" "}\n"); ASSERT_EQUALS("[test.cpp:2]: (warning, inconclusive) Found suspicious operator '+', result is not used.\n" "[test.cpp:3]: (warning, inconclusive) Found suspicious operator '-', result is not used.\n", errout.str()); } void selfAssignment() { check("void foo()\n" "{\n" " int x = 1;\n" " x = x;\n" " return 0;\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (warning) Redundant assignment of 'x' to itself.\n", errout.str()); check("void foo()\n" "{\n" " int x = x;\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (warning) Redundant assignment of 'x' to itself.\n", errout.str()); check("struct A { int b; };\n" "void foo(A* a1, A* a2) {\n" " a1->b = a1->b;\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (warning) Redundant assignment of 'a1->b' to itself.\n", errout.str()); check("int x;\n" "void f()\n" "{\n" " x = x = 3;\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (warning) Redundant assignment of 'x' to itself.\n", errout.str()); // #4073 (segmentation fault) check("void Foo::myFunc( int a )\n" "{\n" " if (a == 42)\n" " a = a;\n" "}"); check("void foo()\n" "{\n" " int x = 1;\n" " x = x + 1;\n" " return 0;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo()\n" "{\n" " int *x = getx();\n" " *x = x;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo() {\n" " BAR *x = getx();\n" " x = x;\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (warning) Redundant assignment of 'x' to itself.\n", errout.str()); // #2502 - non-primitive type -> there might be some side effects check("void foo()\n" "{\n" " Fred fred; fred = fred;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(int x) {\n" " x = (x == 0);" " func(x);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(int x) {\n" " x = (x != 0);" " func(x);\n" "}"); ASSERT_EQUALS("", errout.str()); // ticket #3001 - false positive check("void foo(int x) {\n" " x = x ? x : 0;\n" "}"); ASSERT_EQUALS("", errout.str()); // #3800 - false negative when variable is extern check("extern int i;\n" "void f() {\n" " i = i;\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (warning) Redundant assignment of 'i' to itself.\n", errout.str()); // #4291 - id for variables accessed through 'this' check("class Foo {\n" " int var;\n" " void func();\n" "};\n" "void Foo::func() {\n" " this->var = var;\n" "}"); ASSERT_EQUALS("[test.cpp:6]: (warning) Redundant assignment of 'this->var' to itself.\n", errout.str()); check("class Foo {\n" " int var;\n" " void func(int var);\n" "};\n" "void Foo::func(int var) {\n" " this->var = var;\n" "}"); ASSERT_EQUALS("", errout.str()); // #6406 - designated initializer doing bogus self assignment check("struct callbacks {\n" " void (*s)(void);\n" "};\n" "void something(void) {}\n" "void f() {\n" " struct callbacks ops = { .s = ops.s };\n" "}"); TODO_ASSERT_EQUALS("[test.cpp:6]: (warning) Redundant assignment of 'something' to itself.\n", "", errout.str()); check("class V\n" "{\n" "public:\n" " V()\n" " {\n" " x = y = z = 0.0;\n" " }\n" " V( double x, const double y_, const double &z_)\n" " {\n" " x = x; y = y; z = z;\n" " }\n" " double x, y, z;\n" "};"); ASSERT_EQUALS("[test.cpp:10]: (warning) Redundant assignment of 'x' to itself.\n" "[test.cpp:10]: (warning) Redundant assignment of 'y' to itself.\n" "[test.cpp:10]: (warning) Redundant assignment of 'z' to itself.\n", errout.str()); check("void f(int i) { i = !!i; }"); ASSERT_EQUALS("", errout.str()); check("void foo() {\n" " int x = 1;\n" " int &ref = x;\n" " ref = x;\n" "}\n"); ASSERT_EQUALS("[test.cpp:4]: (warning) Redundant assignment of 'ref' to itself.\n", errout.str()); check("class Foo {\n" // #9850 " int i{};\n" " void modify();\n" " void method() {\n" " Foo copy = *this;\n" " modify();\n" " *this = copy;\n" " }\n" "};\n"); ASSERT_EQUALS("", errout.str()); check("struct S {\n" // #11383 " void f() {\n" " int x = 42;" " auto l2 = [i = i, x, y = 0]() { return i + x + y; };\n" " }\n" " int i;\n" "};\n"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" // #10337 " int b[2] = { 1, 2 };\n" " int idx = 0;\n" " int& i = b[idx];\n" " idx++;\n" " i = b[idx];\n" "};\n"); ASSERT_EQUALS("", errout.str()); } void trac1132() { check("class Lock\n" "{\n" "public:\n" " Lock(int i)\n" " {\n" " std::cout << \"Lock \" << i << std::endl;\n" " }\n" " ~Lock()\n" " {\n" " std::cout << \"~Lock\" << std::endl;\n" " }\n" "};\n" "int main()\n" "{\n" " Lock(123);\n" " std::cout << \"hello\" << std::endl;\n" " return 0;\n" "}"); ASSERT_EQUALS("[test.cpp:15]: (style) Instance of 'Lock' object is destroyed immediately.\n", errout.str()); } void trac3693() { check("struct A{\n" " enum {\n" " b = 300\n" " };\n" "};\n" "const int DFLT_TIMEOUT = A::b % 1000000 ;\n", nullptr, false, false); ASSERT_EQUALS("", errout.str()); } void testMisusedScopeObjectDoesNotPickFunction1() { check("int main ( )\n" "{\n" " CouldBeFunction ( 123 ) ;\n" " return 0 ;\n" "}"); ASSERT_EQUALS("", errout.str()); } void testMisusedScopeObjectDoesNotPickFunction2() { check("struct error {\n" " error() {}\n" "};\n" "\n" "class parser {\n" "public:\n" " void error() const {}\n" "\n" " void foo() const {\n" " error();\n" " do_something();\n" " }\n" "};"); ASSERT_EQUALS("", errout.str()); } void testMisusedScopeObjectPicksClass() { check("class NotAFunction ;\n" "int function ( )\n" "{\n" " NotAFunction ( 123 );\n" " return 0 ;\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (style) Instance of 'NotAFunction' object is destroyed immediately.\n", errout.str()); } void testMisusedScopeObjectPicksStruct() { check("struct NotAClass;\n" "bool func ( )\n" "{\n" " NotAClass ( 123 ) ;\n" " return true ;\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (style) Instance of 'NotAClass' object is destroyed immediately.\n", errout.str()); } void testMisusedScopeObjectDoesNotPickIf() { check("bool func( int a , int b , int c )\n" "{\n" " if ( a > b ) return c == a ;\n" " return b == a ;\n" "}"); ASSERT_EQUALS("", errout.str()); } void testMisusedScopeObjectDoesNotPickConstructorDeclaration() { check("class Something : public SomethingElse\n" "{\n" "public:\n" "~Something ( ) ;\n" "Something ( ) ;\n" "}"); ASSERT_EQUALS("", errout.str()); } void testMisusedScopeObjectDoesNotPickFunctor() { check("class IncrementFunctor\n" "{\n" "public:\n" " void operator()(int &i)\n" " {\n" " ++i;\n" " }\n" "};\n" "\n" "int main()\n" "{\n" " int a = 1;\n" " IncrementFunctor()(a);\n" " return a;\n" "}"); ASSERT_EQUALS("", errout.str()); } void testMisusedScopeObjectDoesNotPickLocalClassConstructors() { check("void f() {\n" " class Foo {\n" " Foo() { }\n" " Foo(int a) { }\n" " Foo(int a, int b) { }\n" " };\n" " Foo();\n" " do_something();\n" "}"); ASSERT_EQUALS("[test.cpp:7]: (style) Instance of 'Foo' object is destroyed immediately.\n", errout.str()); } void testMisusedScopeObjectDoesNotPickUsedObject() { check("struct Foo {\n" " void bar() {\n" " }\n" "};\n" "\n" "void fn() {\n" " Foo().bar();\n" "}"); ASSERT_EQUALS("", errout.str()); } void testMisusedScopeObjectDoesNotPickPureC() { // Ticket #2352 const char code[] = "struct cb_watch_bool {\n" " int a;\n" "};\n" "\n" "void f()\n" "{\n" " cb_watch_bool();\n" " do_something();\n" "}\n"; check(code, "test.cpp"); ASSERT_EQUALS("[test.cpp:7]: (style) Instance of 'cb_watch_bool' object is destroyed immediately.\n", errout.str()); check(code, "test.c"); ASSERT_EQUALS("", errout.str()); // Ticket #2639 check("struct stat { int a; int b; };\n" "void stat(const char *fn, struct stat *);\n" "\n" "void foo() {\n" " stat(\"file.txt\", &st);\n" " do_something();\n" "}"); ASSERT_EQUALS("",errout.str()); check("struct AMethodObject {\n" // #4336 " AMethodObject(double, double, double);\n" "};\n" "struct S {\n" " static void A(double, double, double);\n" "};\n" "void S::A(double const a1, double const a2, double const a3) {\n" " AMethodObject(a1, a2, a3);\n" "}\n"); ASSERT_EQUALS("",errout.str()); } void testMisusedScopeObjectDoesNotPickNestedClass() { const char code[] = "class ios_base {\n" "public:\n" " class Init {\n" " public:\n" " };\n" "};\n" "class foo {\n" "public:\n" " foo();\n" " void Init(int);\n" "};\n" "foo::foo() {\n" " Init(0);\n" " do_something();\n" "}\n"; check(code, "test.cpp"); ASSERT_EQUALS("", errout.str()); } void testMisusedScopeObjectInConstructor() { const char code[] = "class Foo {\n" "public:\n" " Foo(char x) {\n" " Foo(x, 0);\n" " do_something();\n" " }\n" " Foo(char x, int y) { }\n" "};\n"; check(code, "test.cpp"); ASSERT_EQUALS("[test.cpp:4]: (style) Instance of 'Foo' object is destroyed immediately.\n", errout.str()); } void testMisusedScopeObjectStandardType() { check("int g();\n" "void f(int i) {\n" " int();\n" " int(0);\n" " int( g() );\n" // don't warn " int{};\n" " int{ 0 };\n" " int{ i };\n" " int{ g() };\n" // don't warn " g();\n" "}\n", "test.cpp"); ASSERT_EQUALS("[test.cpp:3]: (style) Instance of 'int' object is destroyed immediately.\n" "[test.cpp:4]: (style) Instance of 'int' object is destroyed immediately.\n" "[test.cpp:6]: (style) Instance of 'int' object is destroyed immediately.\n" "[test.cpp:7]: (style) Instance of 'int' object is destroyed immediately.\n" "[test.cpp:8]: (style) Instance of 'int' object is destroyed immediately.\n", errout.str()); check("void f(int j) {\n" " for (; bool(j); ) {}\n" "}\n", "test.cpp"); ASSERT_EQUALS("", errout.str()); check("void g() {\n" " float (f);\n" " float (*p);\n" "}\n", "test.cpp"); ASSERT_EQUALS("", errout.str()); check("int f(int i) {\n" " void();\n" " return i;\n" "}\n", "test.cpp"); ASSERT_EQUALS("", errout.str()); } void testMisusedScopeObjectNamespace() { check("namespace M {\n" // #4779 " namespace N {\n" " struct S {};\n" " }\n" "}\n" "int f() {\n" " M::N::S();\n" " return 0;\n" "}\n", "test.cpp"); ASSERT_EQUALS("[test.cpp:7]: (style) Instance of 'M::N::S' object is destroyed immediately.\n", errout.str()); check("void f() {\n" // #10057 " std::string(\"abc\");\n" " std::string{ \"abc\" };\n" " std::pair(1, 2);\n" " (void)0;\n" "}\n", "test.cpp"); ASSERT_EQUALS("[test.cpp:2]: (style) Instance of 'std::string' object is destroyed immediately.\n" "[test.cpp:3]: (style) Instance of 'std::string' object is destroyed immediately.\n" "[test.cpp:4]: (style) Instance of 'std::pair' object is destroyed immediately.\n", errout.str()); check("struct S {\n" // #10083 " void f() {\n" " std::lock_guard(m);\n" " }\n" " void g() {\n" " std::scoped_lock(m);\n" " }\n" " void h() {\n" " std::scoped_lock(m);\n" " }\n" " std::mutex m;\n" "}\n", "test.cpp"); ASSERT_EQUALS("[test.cpp:3]: (style) Instance of 'std::lock_guard' object is destroyed immediately.\n" "[test.cpp:6]: (style) Instance of 'std::scoped_lock' object is destroyed immediately.\n" "[test.cpp:9]: (style) Instance of 'std::scoped_lock' object is destroyed immediately.\n", errout.str()); } void testMisusedScopeObjectAssignment() { // #11371 check("struct S;\n" "S f();\n" "S& g();\n" "S&& h();\n" "S* i();\n" "void t0() { f() = {}; }\n" "void t1() { g() = {}; }\n" "void t2() { h() = {}; }\n" "void t3() { *i() = {}; }\n", "test.cpp"); ASSERT_EQUALS("[test.cpp:6]: (style) Instance of 'S' object is destroyed immediately, assignment has no effect.\n", errout.str()); } void trac2084() { check("void f()\n" "{\n" " struct sigaction sa;\n" "\n" " { sigaction(SIGHUP, &sa, 0); };\n" " { sigaction(SIGINT, &sa, 0); };\n" "}"); ASSERT_EQUALS("", errout.str()); } void trac2071() { check("void f() {\n" " struct AB {\n" " AB(int a) { }\n" " };\n" "\n" " const AB ab[3] = { AB(0), AB(1), AB(2) };\n" "}"); ASSERT_EQUALS("", errout.str()); } void clarifyCalculation() { check("int f(char c) {\n" " return 10 * (c == 0) ? 1 : 2;\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Clarify calculation precedence for '*' and '?'.\n", errout.str()); check("void f(char c) {\n" " printf(\"%i\", 10 * (c == 0) ? 1 : 2);\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Clarify calculation precedence for '*' and '?'.\n", errout.str()); check("void f() {\n" " return (2*a)?b:c;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(char c) {\n" " printf(\"%i\", a + b ? 1 : 2);\n" "}",nullptr,false,false); ASSERT_EQUALS("[test.cpp:2]: (style) Clarify calculation precedence for '+' and '?'.\n", errout.str()); check("void f() {\n" " std::cout << x << y ? 2 : 3;\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Clarify calculation precedence for '<<' and '?'.\n", errout.str()); check("void f() {\n" " int ab = a - b ? 2 : 3;\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Clarify calculation precedence for '-' and '?'.\n", errout.str()); check("void f() {\n" " int ab = a | b ? 2 : 3;\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Clarify calculation precedence for '|' and '?'.\n", errout.str()); // ticket #195 check("int f(int x, int y) {\n" " return x >> ! y ? 8 : 2;\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Clarify calculation precedence for '>>' and '?'.\n", errout.str()); check("int f() {\n" " return shift < sizeof(int64_t)*8 ? 1 : 2;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() { a = *p ? 1 : 2; }"); ASSERT_EQUALS("", errout.str()); check("void f(int x) { const char *p = x & 1 ? \"1\" : \"0\"; }"); ASSERT_EQUALS("", errout.str()); check("void foo() { x = a % b ? \"1\" : \"0\"; }"); ASSERT_EQUALS("", errout.str()); check("void f(int x) { return x & 1 ? '1' : '0'; }"); ASSERT_EQUALS("", errout.str()); check("void f(int x) { return x & 16 ? 1 : 0; }"); ASSERT_EQUALS("", errout.str()); check("void f(int x) { return x % 16 ? 1 : 0; }"); ASSERT_EQUALS("", errout.str()); check("enum {X,Y}; void f(int x) { return x & Y ? 1 : 0; }"); ASSERT_EQUALS("", errout.str()); } void clarifyStatement() { check("char* f(char* c) {\n" " *c++;\n" " return c;\n" "}"); ASSERT_EQUALS( "[test.cpp:2]: (warning, inconclusive) Found suspicious operator '*', result is not used.\n" "[test.cpp:2]: (warning) In expression like '*A++' the result of '*' is unused. Did you intend to write '(*A)++;'?\n", errout.str()); check("char* f(char** c) {\n" " *c[5]--;\n" " return *c;\n" "}"); ASSERT_EQUALS( "[test.cpp:2]: (warning, inconclusive) Found suspicious operator '*', result is not used.\n" "[test.cpp:2]: (warning) In expression like '*A++' the result of '*' is unused. Did you intend to write '(*A)++;'?\n", errout.str()); check("void f(Foo f) {\n" " *f.a++;\n" "}"); ASSERT_EQUALS( "[test.cpp:2]: (warning, inconclusive) Found suspicious operator '*', result is not used.\n" "[test.cpp:2]: (warning) In expression like '*A++' the result of '*' is unused. Did you intend to write '(*A)++;'?\n", errout.str()); check("void f(Foo f) {\n" " *f.a[5].v[3]++;\n" "}"); ASSERT_EQUALS( "[test.cpp:2]: (warning, inconclusive) Found suspicious operator '*', result is not used.\n" "[test.cpp:2]: (warning) In expression like '*A++' the result of '*' is unused. Did you intend to write '(*A)++;'?\n", errout.str()); check("void f(Foo f) {\n" " *f.a(1, 5).v[x + y]++;\n" "}"); ASSERT_EQUALS( "[test.cpp:2]: (warning, inconclusive) Found suspicious operator '*', result is not used.\n" "[test.cpp:2]: (warning) In expression like '*A++' the result of '*' is unused. Did you intend to write '(*A)++;'?\n", errout.str()); check("char* f(char* c) {\n" " (*c)++;\n" " return c;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(char* c) {\n" " bar(*c++);\n" "}"); ASSERT_EQUALS("", errout.str()); check("char*** f(char*** c) {\n" " ***c++;\n" " return c;\n" "}"); ASSERT_EQUALS( "[test.cpp:2]: (warning, inconclusive) Found suspicious operator '*', result is not used.\n" "[test.cpp:2]: (warning) In expression like '*A++' the result of '*' is unused. Did you intend to write '(*A)++;'?\n", errout.str()); check("char** f(char*** c) {\n" " **c[5]--;\n" " return **c;\n" "}"); ASSERT_EQUALS( "[test.cpp:2]: (warning, inconclusive) Found suspicious operator '*', result is not used.\n" "[test.cpp:2]: (warning) In expression like '*A++' the result of '*' is unused. Did you intend to write '(*A)++;'?\n", errout.str()); check("char*** f(char*** c) {\n" " (***c)++;\n" " return c;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(const int*** p) {\n" // #10923 " delete[] **p;\n" "}\n"); ASSERT_EQUALS("", errout.str()); check("void *f(char** c) {\n" " bar(**c++);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void *f(char* p) {\n" " for (p = path; *p++;) ;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " std::array,3> array;\n" "}\n"); ASSERT_EQUALS("", errout.str()); } void duplicateBranch() { check("void f(int a, int &b) {\n" " if (a)\n" " b = 1;\n" " else\n" " b = 1;\n" "}"); ASSERT_EQUALS("[test.cpp:4] -> [test.cpp:2]: (style, inconclusive) Found duplicate branches for 'if' and 'else'.\n", errout.str()); check("void f(int a, int &b) {\n" " if (a) {\n" " if (a == 1)\n" " b = 2;\n" " else\n" " b = 2;\n" " } else\n" " b = 1;\n" "}"); ASSERT_EQUALS("[test.cpp:5] -> [test.cpp:3]: (style, inconclusive) Found duplicate branches for 'if' and 'else'.\n", errout.str()); check("void f(int a, int &b) {\n" " if (a == 1)\n" " b = 1;\n" " else {\n" " if (a)\n" " b = 2;\n" " else\n" " b = 2;\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:7] -> [test.cpp:5]: (style, inconclusive) Found duplicate branches for 'if' and 'else'.\n", errout.str()); check("int f(int signed, unsigned char value) {\n" " int ret;\n" " if (signed)\n" " ret = (signed char)value;\n" // cast must be kept so the simplifications and verification is skipped " else\n" " ret = (unsigned char)value;\n" " return ret;\n" "}", nullptr, false, false); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " if (b)\n" " __asm__(\"mov ax, bx\");\n" " else\n" " __asm__(\"mov bx, bx\");\n" "}"); ASSERT_EQUALS("", errout.str()); // #3407 check("void f() {\n" " if (b)\n" " __asm__(\"mov ax, bx\");\n" " else\n" " __asm__(\"mov ax, bx\");\n" "}"); ASSERT_EQUALS("[test.cpp:4] -> [test.cpp:2]: (style, inconclusive) Found duplicate branches for 'if' and 'else'.\n", errout.str()); } void duplicateBranch1() { // tests inspired by http://www.viva64.com/en/b/0149/ ( Comparison between PVS-Studio and cppcheck ) // Errors detected in Quake 3: Arena by PVS-Studio: Fragment 2 check("void f()\n" "{\n" " if (front < 0)\n" " frac = front/(front-back);\n" " else\n" " frac = front/(front-back);\n" "}"); ASSERT_EQUALS("[test.cpp:5] -> [test.cpp:3]: (style, inconclusive) Found duplicate branches for 'if' and 'else'.\n", errout.str()); check("void f()\n" "{\n" " if (front < 0)\n" " { frac = front/(front-back);}\n" " else\n" " frac = front/((front-back));\n" "}"); ASSERT_EQUALS("[test.cpp:5] -> [test.cpp:3]: (style, inconclusive) Found duplicate branches for 'if' and 'else'.\n", errout.str()); // No message about empty branches (#5354) check("void f()\n" "{\n" " if (front < 0)\n" " {}\n" " else\n" " {}\n" "}"); ASSERT_EQUALS("", errout.str()); } void duplicateBranch2() { checkP("#define DOSTUFF1 ;\n" "#define DOSTUFF2 ;\n" "void f(int x) {\n" // #4329 " if (x)\n" " DOSTUFF1\n" " else\n" " DOSTUFF2\n" "}"); ASSERT_EQUALS("", errout.str()); } void duplicateBranch3() { check("void f(bool b, int i) {\n" " int j = i;\n" " if (b) {\n" " x = i;\n" " } else {\n" " x = j;\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:5] -> [test.cpp:3]: (style, inconclusive) Found duplicate branches for 'if' and 'else'.\n" "[test.cpp:2]: (style) The scope of the variable 'j' can be reduced.\n", errout.str()); check("void f(bool b, int i) {\n" " int j = i;\n" " i++;\n" " if (b) {\n" " x = i;\n" " } else {\n" " x = j;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); } void duplicateBranch4() { check("void* f(bool b) {\n" " if (b) {\n" " return new A::Y(true);\n" " } else {\n" " return new A::Z(true);\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); } void duplicateBranch5() { check("void f(bool b) {\n" " int j;\n" " if (b) {\n" " unsigned int i = 0;\n" " j = i;\n" " } else {\n" " unsigned int i = 0;\n" " j = i;\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:6] -> [test.cpp:3]: (style, inconclusive) Found duplicate branches for 'if' and 'else'.\n", errout.str()); check("void f(bool b) {\n" " int j;\n" " if (b) {\n" " unsigned int i = 0;\n" " j = i;\n" " } else {\n" " unsigned int i = 0;\n" " j = 1;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(bool b) {\n" " int j;\n" " if (b) {\n" " unsigned int i = 0;\n" " } else {\n" " int i = 0;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(bool b) {\n" " int j;\n" " if (b) {\n" " unsigned int i = 0;\n" " j = i;\n" " } else {\n" " int i = 0;\n" " j = i;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); } void duplicateBranch6() { check("void f(bool b) {\n" " if (b) {\n" " } else {\n" " int i = 0;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(bool b) {\n" " if (b) {\n" " int i = 0;\n" " } else {\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); } void duplicateExpression1() { check("void foo(int a) {\n" " if (a == a) { }\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '=='.\n", errout.str()); check("void fun(int b) {\n" " return a && a ||\n" " b == b &&\n" " d > d &&\n" " e < e &&\n" " f ;\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '&&'.\n" "[test.cpp:3]: (style) Same expression on both sides of '=='.\n" "[test.cpp:4]: (style) Same expression on both sides of '>'.\n" "[test.cpp:5]: (style) Same expression on both sides of '<'.\n", errout.str()); check("void foo() {\n" " return a && a;\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '&&'.\n", errout.str()); check("void foo() {\n" " a = b && b;\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '&&'.\n", errout.str()); check("void foo(int b) {\n" " f(a,b == b);\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '=='.\n", errout.str()); check("void foo(int b) {\n" " f(b == b, a);\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '=='.\n", errout.str()); check("void foo() {\n" " if (x!=2 || x!=2) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '||'.\n", errout.str()); check("void foo(int a, int b) {\n" " if ((a < b) && (b > a)) { }\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '&&' because 'aa' represent the same value.\n", errout.str()); check("void foo(int a, int b) {\n" " if ((a <= b) && (b >= a)) { }\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '&&' because 'a<=b' and 'b>=a' represent the same value.\n", errout.str()); check("void foo() {\n" " if (x!=2 || y!=3 || x!=2) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression 'x!=2' found multiple times in chain of '||' operators.\n", errout.str()); check("void foo() {\n" " if (x!=2 && (x=y) && x!=2) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo() {\n" " if (a && b || a && b) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '||'.\n", errout.str()); check("void foo() {\n" " if (a && b || b && c) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo() {\n" " if (a && b | b && c) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '|'.\n", errout.str()); check("void foo() {\n" " if ((a + b) | (a + b)) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '|'.\n", errout.str()); check("void foo() {\n" " if ((a | b) & (a | b)) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '&'.\n", errout.str()); check("void foo(int a, int b) {\n" " if ((a | b) == (a | b)) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '=='.\n", errout.str()); check("void foo() {\n" " if (a1[a2[c & 0xff] & 0xff]) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void d(const char f, int o, int v)\n" "{\n" " if (((f=='R') && (o == 1) && ((v < 2) || (v > 99))) ||\n" " ((f=='R') && (o == 2) && ((v < 2) || (v > 99))) ||\n" " ((f=='T') && (o == 2) && ((v < 200) || (v > 9999)))) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("int f(int x) { return x+x; }"); ASSERT_EQUALS("", errout.str()); check("void f(int x) { while (x+=x) ; }"); ASSERT_EQUALS("", errout.str()); check("void foo() {\n" " if (a && b && b) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '&&'.\n", errout.str()); check("void foo() {\n" " if (a || b || b) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '||'.\n", errout.str()); check("void foo() {\n" " if (a / 1000 / 1000) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("int foo(int i) {\n" " return i/i;\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '/'.\n", errout.str()); check("void foo() {\n" " if (a << 1 << 1) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("int f() { return !!y; }"); // No FP ASSERT_EQUALS("", errout.str()); // make sure there are not "same expression" fp when there are different casts check("void f(long x) { if ((int32_t)x == (int64_t)x) {} }", nullptr, // filename false, // inconclusive false, // runSimpleChecks false, // verbose nullptr // settings ); ASSERT_EQUALS("", errout.str()); // make sure there are not "same expression" fp when there are different ({}) expressions check("void f(long x) { if (({ 1+2; }) == ({3+4;})) {} }"); ASSERT_EQUALS("", errout.str()); // #5535: Reference named like its type check("void foo() { UMSConfig& UMSConfig = GetUMSConfiguration(); }"); ASSERT_EQUALS("[test.cpp:1]: (style) Variable 'UMSConfig' can be declared as reference to const\n", errout.str()); // #3868 - false positive (same expression on both sides of |) check("void f(int x) {\n" " a = x ? A | B | C\n" " : A | B;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(const Bar &bar) {\n" " bool a = bar.isSet() && bar->isSet();\n" " bool b = bar.isSet() && bar.isSet();\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (style) Same expression on both sides of '&&'.\n", errout.str()); check("void foo(int a, int b) {\n" " if ((b + a) | (a + b)) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '|' because 'b+a' and 'a+b' represent the same value.\n", errout.str()); check("void foo(const std::string& a, const std::string& b) {\n" " return a.find(b+\"&\") || a.find(\"&\"+b);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(int a, int b) {\n" " if ((b > a) | (a > b)) {}\n" // > is not commutative "}"); ASSERT_EQUALS("", errout.str()); check("void foo(double a, double b) {\n" " if ((b + a) > (a + b)) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) The comparison 'b+a > a+b' is always false because 'b+a' and 'a+b' represent the same value.\n", errout.str()); check("void f(int x) {\n" " if ((x == 1) && (x == 0x00000001))\n" " a++;\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '&&' because 'x==1' and 'x==0x00000001' represent the same value.\n", errout.str()); check("void f() {\n" " enum { Four = 4 };\n" " if (Four == 4) {}" "}", nullptr, true, false); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " enum { Four = 4 };\n" " static_assert(Four == 4, \"\");\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " enum { Four = 4 };\n" " static_assert(4 == Four, \"\");\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " enum { FourInEnumOne = 4 };\n" " enum { FourInEnumTwo = 4 };\n" " if (FourInEnumOne == FourInEnumTwo) {}\n" "}", nullptr, true, false); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " enum { FourInEnumOne = 4 };\n" " enum { FourInEnumTwo = 4 };\n" " static_assert(FourInEnumOne == FourInEnumTwo, \"\");\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(int a, int b) {\n" " if (sizeof(a) == sizeof(a)) { }\n" " if (sizeof(a) == sizeof(b)) { }\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '=='.\n", errout.str()); check("float bar(int) __attribute__((pure));\n" "char foo(int) __attribute__((pure));\n" "int test(int a, int b) {\n" " if (bar(a) == bar(a)) { }\n" " if (unknown(a) == unknown(a)) { }\n" " if (foo(a) == foo(a)) { }\n" "}"); ASSERT_EQUALS("[test.cpp:6]: (style) Same expression on both sides of '=='.\n", errout.str()); } void duplicateExpression2() { // check if float is NaN or Inf check("int f(long double ldbl, double dbl, float flt) {\n" // ticket #2730 " if (ldbl != ldbl) have_nan = 1;\n" " if (!(dbl == dbl)) have_nan = 1;\n" " if (flt != flt) have_nan = 1;\n" " return have_nan;\n" "}"); ASSERT_EQUALS("", errout.str()); check("float f(float x) { return x-x; }"); // ticket #4485 (Inf) ASSERT_EQUALS("", errout.str()); check("float f(float x) { return (X double)x == (X double)x; }", nullptr, false, false); ASSERT_EQUALS("", errout.str()); check("struct X { float f; };\n" "float f(struct X x) { return x.f == x.f; }"); ASSERT_EQUALS("", errout.str()); check("struct X { int i; };\n" "int f(struct X x) { return x.i == x.i; }"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '=='.\n", errout.str()); // #5284 - when type is unknown, assume it's float check("int f() { return x==x; }"); ASSERT_EQUALS("", errout.str()); } void duplicateExpression3() { const char xmldata[] = "\n" "\n" " \n" " \n" " \n" " \n" " \n" ""; Settings settings = settingsBuilder().libraryxml(xmldata, sizeof(xmldata)).build(); check("void foo() {\n" " if (x() || x()) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("struct A {\n" " void foo() const;\n" " bool bar() const;\n" "};\n" "void A::foo() const {\n" " if (bar() && bar()) {}\n" "}"); ASSERT_EQUALS("[test.cpp:6]: (style) Same expression on both sides of '&&'.\n", errout.str()); check("struct A {\n" " void foo();\n" " bool bar();\n" " bool bar() const;\n" "};\n" "void A::foo() {\n" " if (bar() && bar()) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("class B {\n" " void bar(int i);\n" "};\n" "class A {\n" " void bar(int i) const;\n" "};\n" "void foo() {\n" " B b;\n" " A a;\n" " if (b.bar(1) && b.bar(1)) {}\n" " if (a.bar(1) && a.bar(1)) {}\n" "}"); ASSERT_EQUALS("[test.cpp:11]: (style) Same expression on both sides of '&&'.\n", errout.str()); check("class D { void strcmp(); };\n" "void foo() {\n" " D d;\n" " if (d.strcmp() && d.strcmp()) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo() {\n" " if ((mystrcmp(a, b) == 0) || (mystrcmp(a, b) == 0)) {}\n" "}", "test.cpp", false, true, false, &settings); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '||'.\n", errout.str()); check("void GetValue() { return rand(); }\n" "void foo() {\n" " if ((GetValue() == 0) || (GetValue() == 0)) { dostuff(); }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void __attribute__((const)) GetValue() { return X; }\n" "void foo() {\n" " if ((GetValue() == 0) || (GetValue() == 0)) { dostuff(); }\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (style) Same expression on both sides of '||'.\n", errout.str()); check("void GetValue() __attribute__((const));\n" "void GetValue() { return X; }\n" "void foo() {\n" " if ((GetValue() == 0) || (GetValue() == 0)) { dostuff(); }\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (style) Same expression on both sides of '||'.\n", errout.str()); check("void foo() {\n" " if (str == \"(\" || str == \"(\") {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '||'.\n", errout.str()); check("void foo() {\n" " if (bar(a) && !strcmp(a, b) && bar(a) && !strcmp(a, b)) {}\n" "}"); ASSERT_EQUALS("", errout.str()); // #5334 check("void f(C *src) {\n" " if (x(src) || x(src))\n" " a++;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(A *src) {\n" " if (dynamic_cast(src) || dynamic_cast(src)) {}\n" "}\n", "test.cpp", false, false); // don't run simplifications ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '||'.\n", errout.str()); // #5819 check("Vector func(Vector vec1) {\n" " return fabs(vec1 & vec1 & vec1);\n" "}"); ASSERT_EQUALS("", errout.str()); check("Vector func(int vec1) {\n" " return fabs(vec1 & vec1 & vec1);\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '&'.\n", errout.str()); } void duplicateExpression4() { check("void foo() {\n" " if (*a++ != b || *a++ != b) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo() {\n" " if (*a-- != b || *a-- != b) {}\n" "}"); ASSERT_EQUALS("", errout.str()); // assignment check("void f() {\n" " while (*(a+=2)==*(b+=2) && *(a+=2)==*(b+=2)) {}\n" "}"); ASSERT_EQUALS("", errout.str()); } void duplicateExpression5() { // #3749 - macros with same values check("void f() {\n" " if ($a == $a) { }\n" "}"); ASSERT_EQUALS("", errout.str()); } void duplicateExpression6() { // #4639 check("float IsNan(float value) { return !(value == value); }\n" "double IsNan(double value) { return !(value == value); }\n" "long double IsNan(long double value) { return !(value == value); }"); ASSERT_EQUALS("", errout.str()); } void duplicateExpression7() { check("void f() {\n" " const int i = sizeof(int);\n" " if ( i != sizeof (int)){}\n" "}"); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:3]: (style) The comparison 'i != sizeof(int)' is always false because 'i' and 'sizeof(int)' represent the same value.\n", errout.str()); check("void f() {\n" " const int i = sizeof(int);\n" " if ( sizeof (int) != i){}\n" "}"); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:3]: (style) The comparison 'sizeof(int) != i' is always false because 'sizeof(int)' and 'i' represent the same value.\n", errout.str()); check("void f(int a = 1) { if ( a != 1){}}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " int a = 1;\n" " if ( a != 1){}\n" "}"); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:3]: (style) The comparison 'a != 1' is always false.\n", errout.str()); check("void f() {\n" " int a = 1;\n" " int b = 1;\n" " if ( a != b){}\n" "}"); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:3] -> [test.cpp:4]: (style) The comparison 'a != b' is always false because 'a' and 'b' represent the same value.\n", errout.str()); check("void f() {\n" " int a = 1;\n" " int b = a;\n" " if ( a != b){}\n" "}"); ASSERT_EQUALS("[test.cpp:3] -> [test.cpp:4]: (style) The comparison 'a != b' is always false because 'a' and 'b' represent the same value.\n", errout.str()); check("void use(int);\n" "void f() {\n" " int a = 1;\n" " int b = 1;\n" " use(b);\n" " if ( a != 1){}\n" "}"); ASSERT_EQUALS("[test.cpp:3] -> [test.cpp:6]: (style) The comparison 'a != 1' is always false.\n", errout.str()); check("void use(int);\n" "void f() {\n" " int a = 1;\n" " use(a);\n" " a = 2;\n" " if ( a != 1){}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void use(int);\n" "void f() {\n" " int a = 2;\n" " use(a);\n" " a = 1;\n" " if ( a != 1){}\n" "}"); ASSERT_EQUALS("", errout.str()); check("const int a = 1;\n" "void f() {\n" " if ( a != 1){}\n" "}"); ASSERT_EQUALS("[test.cpp:1] -> [test.cpp:3]: (style) The comparison 'a != 1' is always false.\n", errout.str()); check("int a = 1;\n" " void f() {\n" " if ( a != 1){}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " static const int a = 1;\n" " if ( a != 1){}\n" "}"); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:3]: (style) The comparison 'a != 1' is always false.\n", errout.str()); check("void f() {\n" " static int a = 1;\n" " if ( a != 1){}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " int a = 1;\n" " if ( a != 1){\n" " a++;\n" " }}"); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:3]: (style) The comparison 'a != 1' is always false.\n", errout.str()); check("void f(int b) {\n" " int a = 1;\n" " while (b) {\n" " if ( a != 1){}\n" " a++;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("bool f(bool a, bool b) {\n" " const bool c = a;\n" " return a && b && c;\n" "}"); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:3]: (style) Same expression 'a' found multiple times in chain of '&&' operators because 'a' and 'c' represent the same value.\n", errout.str()); // 6906 check("void f(const bool b) {\n" " const bool b1 = !b;\n" " if(!b && b1){}\n" "}"); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:3]: (style) Same expression on both sides of '&&' because '!b' and 'b1' represent the same value.\n", errout.str()); // 7284 check("void f(void) {\n" " if (a || !!a) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '||' because 'a' and '!!a' represent the same value.\n", errout.str()); // 8205 check("void f(int x) {\n" " int Diag = 0;\n" " switch (x) {\n" " case 12:\n" " if (Diag==0) {}\n" " break;\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:5]: (style) The comparison 'Diag == 0' is always true.\n", errout.str()); // #9744 check("void f(const std::vector& ints) {\n" " int i = 0;\n" " for (int p = 0; i < ints.size(); ++i) {\n" " if (p == 0) {}\n" " }\n" "}\n"); ASSERT_EQUALS("[test.cpp:3] -> [test.cpp:4]: (style) The comparison 'p == 0' is always true.\n", errout.str()); } void duplicateExpression8() { check("void f() {\n" " int a = 1;\n" " int b = a;\n" " a = 2;\n" " if ( b != a){}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(int * a, int i) { int b = a[i]; a[i] = 2; if ( b != a[i]){}}"); ASSERT_EQUALS("", errout.str()); check("void f(int * a, int i) { int b = *a; *a = 2; if ( b != *a){}}"); ASSERT_EQUALS("", errout.str()); check("struct A { int f() const; };\n" "A g();\n" "void foo() {\n" " for (A x = A();;) {\n" " const int a = x.f();\n" " x = g();\n" " if (x.f() == a) break;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("int f(int i);\n" "struct A {\n" " enum E { B, C };\n" " bool f(E);\n" "};\n" "void foo() {\n" " A a;\n" " const bool x = a.f(A::B);\n" " const bool y = a.f(A::C);\n" " if(!x && !y) return;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo() {\n" " const bool x = a.f(A::B);\n" " const bool y = a.f(A::C);\n" " if (!x && !y) return;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(bool * const b);\n" "void foo() {\n" " bool x = true;\n" " bool y = true;\n" " f(&x);\n" " if (!x && !y) return;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " const int a = {};\n" " if(a == 1) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("volatile const int var = 42;\n" "void f() { if(var == 42) {} }"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " int a = 0;\n" " struct b c;\n" " c.a = &a;\n" " g(&c);\n" " if (a == 0) {}\n" "}"); ASSERT_EQUALS("", errout.str()); } void duplicateExpression9() { // #9320 check("void f() {\n" " uint16_t x = 1000;\n" " uint8_t y = x;\n" " if (x != y) {}\n" "}"); ASSERT_EQUALS("", errout.str()); } void duplicateExpression10() { // #9485 check("int f() {\n" " const int a = 1;\n" " const int b = a-1;\n" " const int c = a+1;\n" " return c;\n" "}"); ASSERT_EQUALS("", errout.str()); } void duplicateExpression11() { check("class Fred {\n" "public:\n" " double getScale() const { return m_range * m_zoom; }\n" " void setZoom(double z) { m_zoom = z; }\n" " void dostuff(int);\n" "private:\n" " double m_zoom;\n" " double m_range;\n" "};\n" "\n" "void Fred::dostuff(int x) {\n" " if (x == 43) {\n" " double old_scale = getScale();\n" " setZoom(m_zoom + 1);\n" " double scale_ratio = getScale() / old_scale;\n" // <- FP " }\n" "}"); ASSERT_EQUALS("", errout.str()); } void duplicateExpression12() { //#10026 check("int f(const std::vector &buffer, const uint8_t index)\n" "{\n" " int var = buffer[index - 1];\n" " return buffer[index - 1] - var;\n" // << "}"); ASSERT_EQUALS("[test.cpp:3] -> [test.cpp:4]: (style) Same expression on both sides of '-'.\n", errout.str()); } void duplicateExpression13() { //#7899 check("void f() {\n" " if (sizeof(long) == sizeof(long long)) {}\n" "}"); ASSERT_EQUALS("", errout.str()); } void duplicateExpression14() { //#9871 check("int f() {\n" " int k = 7;\n" " int* f = &k;\n" " int* g = &k;\n" " return (f + 4 != g + 4);\n" "}\n"); ASSERT_EQUALS("[test.cpp:3] -> [test.cpp:4] -> [test.cpp:5]: (style) The comparison 'f+4 != g+4' is always false because 'f+4' and 'g+4' represent the same value.\n", errout.str()); } void duplicateExpression15() { //#10650 check("bool f() {\n" " const int i = int(0);\n" " return i == 0;\n" "}\n" "bool g() {\n" " const int i = int{ 0 };\n" " return i == 0;\n" "}\n"); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:3]: (style) The comparison 'i == 0' is always true.\n" "[test.cpp:6] -> [test.cpp:7]: (style) The comparison 'i == 0' is always true.\n", errout.str()); } void duplicateExpression16() { check("void f(const std::string& a) {\n" //#10569 " if ((a == \"x\") ||\n" " (a == \"42\") ||\n" " (a == \"y\") ||\n" " (a == \"42\")) {}\n" "}\n" "void g(const std::string& a) {\n" " if ((a == \"42\") ||\n" " (a == \"x\") ||\n" " (a == \"42\") ||\n" " (a == \"y\")) {}\n" "}\n" "void h(const std::string& a) {\n" " if ((a == \"42\") ||\n" " (a == \"x\") ||\n" " (a == \"y\") ||\n" " (a == \"42\")) {}\n" "}\n"); ASSERT_EQUALS("[test.cpp:1] -> [test.cpp:4]: (style) Same expression 'a==\"42\"' found multiple times in chain of '||' operators.\n" "[test.cpp:7] -> [test.cpp:9]: (style) Same expression 'a==\"42\"' found multiple times in chain of '||' operators.\n" "[test.cpp:13] -> [test.cpp:16]: (style) Same expression 'a==\"42\"' found multiple times in chain of '||' operators.\n", errout.str()); check("void f(const char* s) {\n" // #6371 " if (*s == '\x0F') {\n" " if (!s[1] || !s[2] || !s[1])\n" " break;\n" " }\n" "}\n"); ASSERT_EQUALS("[test.cpp:3]: (style) Same expression '!s[1]' found multiple times in chain of '||' operators.\n", errout.str()); } void duplicateExpressionLoop() { check("void f() {\n" " int a = 1;\n" " while ( a != 1){}\n" "}"); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:3]: (style) The comparison 'a != 1' is always false.\n", errout.str()); check("void f() { int a = 1; while ( a != 1){ a++; }}"); ASSERT_EQUALS("", errout.str()); check("void f() { int a = 1; for ( int i=0; i < 3 && a != 1; i++){ a++; }}"); ASSERT_EQUALS("", errout.str()); check("void f(int b) { int a = 1; while (b) { if ( a != 1){} b++; } a++; }"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " for(int i = 0; i < 10;) {\n" " if( i != 0 ) {}\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:3]: (style) The comparison 'i != 0' is always false.\n", errout.str()); check("void f() {\n" " for(int i = 0; i < 10;) {\n" " if( i != 0 ) {}\n" " i++;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " for(int i = 0; i < 10;) {\n" " if( i != 0 ) { i++; }\n" " i++;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " for(int i = 0; i < 10;) {\n" " if( i != 0 ) { i++; }\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " int i = 0;\n" " while(i < 10) {\n" " if( i != 0 ) {}\n" " i++;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(int b) {\n" " while (b) {\n" " int a = 1;\n" " if ( a != 1){}\n" " b++;\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:3] -> [test.cpp:4]: (style) The comparison 'a != 1' is always false.\n", errout.str()); check("struct T {\n" // #11083 " std::string m;\n" " const std::string & str() const { return m; }\n" " T* next();\n" "};\n" "void f(T* t) {\n" " const std::string& s = t->str();\n" " while (t && t->str() == s)\n" " t = t->next();\n" " do {\n" " t = t->next();\n" " } while (t && t->str() == s);\n" " for (; t && t->str() == s; t = t->next());\n" "}\n"); ASSERT_EQUALS("", errout.str()); } void duplicateExpressionTernary() { // #6391 check("void f() {\n" " return A ? x : x;\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression in both branches of ternary operator.\n", errout.str()); check("int f(bool b, int a) {\n" " const int c = a;\n" " return b ? a : c;\n" "}"); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:3]: (style) Same expression in both branches of ternary operator.\n", errout.str()); check("void f() {\n" " return A ? x : z;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(unsigned char c) {\n" " x = y ? (signed char)c : (unsigned char)c;\n" "}"); ASSERT_EQUALS("", errout.str()); check("std::string stringMerge(std::string const& x, std::string const& y) {\n" // #7938 " return ((x > y) ? (y + x) : (x + y));\n" "}"); ASSERT_EQUALS("", errout.str()); // #6426 { const char code[] = "void foo(bool flag) {\n" " bar( (flag) ? ~0u : ~0ul);\n" "}"; Settings settings = _settings; settings.platform.sizeof_int = 4; settings.platform.int_bit = 32; settings.platform.sizeof_long = 4; settings.platform.long_bit = 32; check(code, &settings); ASSERT_EQUALS("[test.cpp:2]: (style) Same value in both branches of ternary operator.\n", errout.str()); settings.platform.sizeof_long = 8; settings.platform.long_bit = 64; check(code, &settings); ASSERT_EQUALS("", errout.str()); } } void duplicateValueTernary() { check("void f() {\n" " if( a ? (b ? false:false): false ) ;\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Same value in both branches of ternary operator.\n", errout.str()); check("int f1(int a) {return (a == 1) ? (int)1 : 1; }"); ASSERT_EQUALS("[test.cpp:1]: (style) Same value in both branches of ternary operator.\n", errout.str()); check("int f2(int a) {return (a == 1) ? (int)1 : (int)1; }"); ASSERT_EQUALS("[test.cpp:1]: (style) Same value in both branches of ternary operator.\n", errout.str()); check("int f3(int a) {return (a == 1) ? 1 : (int)1; }"); ASSERT_EQUALS("[test.cpp:1]: (style) Same value in both branches of ternary operator.\n", errout.str()); check("int f4(int a) {return (a == 1) ? 1 : 1; }"); ASSERT_EQUALS("[test.cpp:1]: (style) Same value in both branches of ternary operator.\n", errout.str()); check("int f5(int a) {return (a == (int)1) ? (int)1 : 1; }"); ASSERT_EQUALS("[test.cpp:1]: (style) Same value in both branches of ternary operator.\n", errout.str()); check("int f6(int a) {return (a == (int)1) ? (int)1 : (int)1; }"); ASSERT_EQUALS("[test.cpp:1]: (style) Same value in both branches of ternary operator.\n", errout.str()); check("int f7(int a) {return (a == (int)1) ? 1 : (int)1; }"); ASSERT_EQUALS("[test.cpp:1]: (style) Same value in both branches of ternary operator.\n", errout.str()); check("int f8(int a) {return (a == (int)1) ? 1 : 1; }"); ASSERT_EQUALS("[test.cpp:1]: (style) Same value in both branches of ternary operator.\n", errout.str()); check("struct Foo {\n" " std::vector bar{1,2,3};\n" " std::vector baz{4,5,6};\n" "};\n" "void f() {\n" " Foo foo;\n" " it = true ? foo.bar.begin() : foo.baz.begin();\n" "}\n"); ASSERT_EQUALS("", errout.str()); check("void f(bool b) {\n" " std::vector bar{1,2,3};\n" " std::vector baz{4,5,6};\n" " std::vector v = b ? bar : baz;\n" "}\n"); ASSERT_EQUALS("", errout.str()); check("void f(bool q) {\n" // #9570 " static int a = 0;\n" " static int b = 0;\n" " int& x = q ? a : b;\n" " ++x;\n" "}\n"); ASSERT_EQUALS("", errout.str()); check("struct S { int a, b; };\n" // #10107 "S f(bool x, S s) {\n" " (x) ? f.a = 42 : f.b = 42;\n" " return f;\n" "}\n"); ASSERT_EQUALS("", errout.str()); check("float f(float x) {\n" // # 11368 " return (x >= 0.0) ? 0.0 : -0.0;\n" "}\n"); ASSERT_EQUALS("", errout.str()); } void duplicateExpressionTemplate() { check("template void f() {\n" // #6930 " if (I >= 0 && I < 3) {}\n" "}\n" "\n" "static auto a = f<0>();"); ASSERT_EQUALS("", errout.str()); check("template\n" // #7754 "void f() {\n" " if (std::is_same_v || std::is_same_v) {}\n" "}\n"); ASSERT_EQUALS("", errout.str()); check("typedef long long int64_t;" "template\n" "void f() {\n" " if (std::is_same_v || std::is_same_v) {}\n" "}\n"); ASSERT_EQUALS("", errout.str()); checkP("#define int32_t int" "template\n" "void f() {\n" " if (std::is_same_v || std::is_same_v) {}\n" "}\n"); ASSERT_EQUALS("", errout.str()); } void duplicateExpressionCompareWithZero() { check("void f(const int* x, bool b) {\n" " if ((x && b) || (x != 0 && b)) {}\n" "}\n"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '||' because 'x&&b' and 'x!=0&&b' represent the same value.\n", errout.str()); check("void f(const int* x, bool b) {\n" " if ((x != 0 && b) || (x && b)) {}\n" "}\n"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '||' because 'x!=0&&b' and 'x&&b' represent the same value.\n", errout.str()); check("void f(const int* x, bool b) {\n" " if ((x && b) || (b && x != 0)) {}\n" "}\n"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '||' because 'x&&b' and 'b&&x!=0' represent the same value.\n", errout.str()); check("void f(const int* x, bool b) {\n" " if ((!x && b) || (x == 0 && b)) {}\n" "}\n"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '||' because '!x&&b' and 'x==0&&b' represent the same value.\n", errout.str()); check("void f(const int* x, bool b) {\n" " if ((x == 0 && b) || (!x && b)) {}\n" "}\n"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '||' because 'x==0&&b' and '!x&&b' represent the same value.\n", errout.str()); check("void f(const int* x, bool b) {\n" " if ((!x && b) || (b && x == 0)) {}\n" "}\n"); ASSERT_EQUALS("[test.cpp:2]: (style) Same expression on both sides of '||' because '!x&&b' and 'b&&x==0' represent the same value.\n", errout.str()); check("struct A {\n" " int* getX() const;\n" " bool getB() const;\n" " void f() {\n" " if ((getX() && getB()) || (getX() != 0 && getB())) {}\n" " }\n" "};\n"); ASSERT_EQUALS("[test.cpp:5]: (style) Same expression on both sides of '||' because 'getX()&&getB()' and 'getX()!=0&&getB()' represent the same value.\n", errout.str()); check("void f(const int* x, bool b) {\n" " if ((x && b) || (x == 0 && b)) {}\n" "}\n"); ASSERT_EQUALS("", errout.str()); check("void f(const int* x, bool b) {\n" " if ((!x && b) || (x != 0 && b)) {}\n" "}\n"); ASSERT_EQUALS("", errout.str()); } void oppositeExpression() { check("void f(bool a) { if(a && !a) {} }"); ASSERT_EQUALS("[test.cpp:1]: (style) Opposite expression on both sides of '&&'.\n", errout.str()); check("void f(bool a) { if(a != !a) {} }"); ASSERT_EQUALS("[test.cpp:1]: (style) Opposite expression on both sides of '!='.\n", errout.str()); check("void f(bool a) { if( a == !(a) ) {}}"); ASSERT_EQUALS("[test.cpp:1]: (style) Opposite expression on both sides of '=='.\n", errout.str()); check("void f(bool a) { if( a != !(a) ) {}}"); ASSERT_EQUALS("[test.cpp:1]: (style) Opposite expression on both sides of '!='.\n", errout.str()); check("void f(bool a) { if( !(a) == a ) {}}"); ASSERT_EQUALS("[test.cpp:1]: (style) Opposite expression on both sides of '=='.\n", errout.str()); check("void f(bool a) { if( !(a) != a ) {}}"); ASSERT_EQUALS("[test.cpp:1]: (style) Opposite expression on both sides of '!='.\n", errout.str()); check("void f(bool a) { if( !(!a) == !(a) ) {}}"); ASSERT_EQUALS("[test.cpp:1]: (style) Opposite expression on both sides of '=='.\n", errout.str()); check("void f(bool a) { if( !(!a) != !(a) ) {}}"); ASSERT_EQUALS("[test.cpp:1]: (style) Opposite expression on both sides of '!='.\n", errout.str()); check("void f1(bool a) {\n" " const bool b = a;\n" " if( a == !(b) ) {}\n" " if( b == !(a) ) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:3]: (style) Opposite expression on both sides of '=='.\n" "[test.cpp:2] -> [test.cpp:4]: (style) Opposite expression on both sides of '=='.\n", errout.str()); check("void f2(const bool *a) {\n" " const bool b = *a;\n" " if( *a == !(b) ) {}\n" " if( b == !(*a) ) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:3]: (style) Opposite expression on both sides of '=='.\n" "[test.cpp:2] -> [test.cpp:4]: (style) Opposite expression on both sides of '=='.\n", errout.str()); check("void f(bool a) { a = !a; }"); ASSERT_EQUALS("", errout.str()); check("void f(int a) { if( a < -a ) {}}"); ASSERT_EQUALS("[test.cpp:1]: (style) Opposite expression on both sides of '<'.\n", errout.str()); check("void f(int a) { a -= -a; }"); ASSERT_EQUALS("", errout.str()); check("void f(int a) { a = a / (-a); }"); ASSERT_EQUALS("", errout.str()); check("bool f(int i){ return !((i - 1) & i); }"); ASSERT_EQUALS("", errout.str()); check("bool f(unsigned i){ return (x > 0) && (x & (x-1)) == 0; }"); ASSERT_EQUALS("", errout.str()); check("void A::f(bool a, bool c)\n" "{\n" " const bool b = a;\n" " if(c) { a = false; }\n" " if(b && !a) { }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(bool c) {\n" " const bool b = a;\n" " if(c) { a = false; }\n" " if(b && !a) { }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " bool x = a;\n" " dostuff();\n" " if (x && a) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " const bool b = g();\n" " if (!b && g()) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(const bool *a) {\n" " const bool b = a[42];\n" " if( b == !(a[42]) ) {}\n" "}\n"); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:3]: (style) Opposite expression on both sides of '=='.\n", errout.str()); check("void f(const bool *a) {\n" " const bool b = a[42];\n" " if( a[42] == !(b) ) {}\n" "}\n"); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:3]: (style) Opposite expression on both sides of '=='.\n", errout.str()); check("void f(const bool *a) {\n" " const bool b = *a;\n" " if( b == !(*a) ) {}\n" "}\n"); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:3]: (style) Opposite expression on both sides of '=='.\n", errout.str()); check("void f(const bool *a) {\n" " const bool b = *a;\n" " if( *a == !(b) ) {}\n" "}\n"); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:3]: (style) Opposite expression on both sides of '=='.\n", errout.str()); check("void f(uint16_t u) {\n" // #9342 " if (u != (u & -u))\n" " return false;\n" " if (u != (-u & u))\n" " return false;\n" " return true;\n" "}\n"); ASSERT_EQUALS("", errout.str()); } void duplicateVarExpression() { check("int f() __attribute__((pure));\n" "int g() __attribute__((pure));\n" "void test() {\n" " int i = f();\n" " int j = f();\n" "}"); ASSERT_EQUALS("[test.cpp:5] -> [test.cpp:4]: (style) Same expression used in consecutive assignments of 'i' and 'j'.\n", errout.str()); check("struct Foo { int f() const; int g() const; };\n" "void test() {\n" " Foo f = Foo{};\n" " int i = f.f();\n" " int j = f.f();\n" "}"); ASSERT_EQUALS("[test.cpp:5] -> [test.cpp:4]: (style) Same expression used in consecutive assignments of 'i' and 'j'.\n", errout.str()); check("struct Foo { int f() const; int g() const; };\n" "void test() {\n" " Foo f = Foo{};\n" " Foo f2 = Foo{};\n" " int i = f.f();\n" " int j = f.f();\n" "}"); ASSERT_EQUALS("[test.cpp:6] -> [test.cpp:5]: (style) Same expression used in consecutive assignments of 'i' and 'j'.\n", errout.str()); check("int f() __attribute__((pure));\n" "int g() __attribute__((pure));\n" "void test() {\n" " int i = 1 + f();\n" " int j = 1 + f();\n" "}"); ASSERT_EQUALS("[test.cpp:5] -> [test.cpp:4]: (style) Same expression used in consecutive assignments of 'i' and 'j'.\n", errout.str()); check("int f() __attribute__((pure));\n" "int g() __attribute__((pure));\n" "void test() {\n" " int i = f() + 1;\n" " int j = 1 + f();\n" "}"); ASSERT_EQUALS("", errout.str()); check("int f() __attribute__((pure));\n" "int g() __attribute__((pure));\n" "void test() {\n" " int x = f();\n" " int i = x + 1;\n" " int j = f() + 1;\n" "}"); ASSERT_EQUALS("", errout.str()); check("int f() __attribute__((pure));\n" "int g() __attribute__((pure));\n" "void test() {\n" " int i = f() + f();\n" " int j = f() + f();\n" "}"); ASSERT_EQUALS("[test.cpp:5] -> [test.cpp:4]: (style) Same expression used in consecutive assignments of 'i' and 'j'.\n", errout.str()); check("int f(int) __attribute__((pure));\n" "int g(int) __attribute__((pure));\n" "void test() {\n" " int i = f(0);\n" " int j = f(0);\n" "}"); ASSERT_EQUALS("[test.cpp:5] -> [test.cpp:4]: (style) Same expression used in consecutive assignments of 'i' and 'j'.\n", errout.str()); check("int f(int) __attribute__((pure));\n" "int g(int) __attribute__((pure));\n" "void test() {\n" " const int x = 0;\n" " int i = f(0);\n" " int j = f(x);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void test(const int * p, const int * q) {\n" " int i = *p;\n" " int j = *p;\n" "}"); ASSERT_EQUALS("[test.cpp:3] -> [test.cpp:2]: (style) Same expression used in consecutive assignments of 'i' and 'j'.\n", errout.str()); check("struct A { int x; int y; };" "void test(A a) {\n" " int i = a.x;\n" " int j = a.x;\n" "}"); ASSERT_EQUALS("[test.cpp:3] -> [test.cpp:2]: (style) Same expression used in consecutive assignments of 'i' and 'j'.\n", errout.str()); check("void test() {\n" " int i = 0;\n" " int j = 0;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void test() {\n" " int i = -1;\n" " int j = -1;\n" "}"); ASSERT_EQUALS("", errout.str()); check("int f(int);\n" "void test() {\n" " int i = f(0);\n" " int j = f(1);\n" "}"); ASSERT_EQUALS("", errout.str()); check("int f();\n" "int g();\n" "void test() {\n" " int i = f() || f();\n" " int j = f() && f();\n" "}"); ASSERT_EQUALS("", errout.str()); check("struct Foo {};\n" "void test() {\n" " Foo i = Foo();\n" " Foo j = Foo();\n" "}"); ASSERT_EQUALS("", errout.str()); check("struct Foo {};\n" "void test() {\n" " Foo i = Foo{};\n" " Foo j = Foo{};\n" "}"); ASSERT_EQUALS("", errout.str()); check("struct Foo { int f() const; float g() const; };\n" "void test() {\n" " Foo f = Foo{};\n" " int i = f.f();\n" " int j = f.f();\n" "}"); ASSERT_EQUALS("[test.cpp:5] -> [test.cpp:4]: (style, inconclusive) Same expression used in consecutive assignments of 'i' and 'j'.\n", errout.str()); check("struct Foo { int f(); int g(); };\n" "void test() {\n" " Foo f = Foo{};\n" " int i = f.f();\n" " int j = f.f();\n" "}"); ASSERT_EQUALS("", errout.str()); check("void test() {\n" " int i = f();\n" " int j = f();\n" "}"); ASSERT_EQUALS("", errout.str()); check("void test(int x) {\n" " int i = ++x;\n" " int j = ++x;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void test(int x) {\n" " int i = x++;\n" " int j = x++;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void test(int x) {\n" " int i = --x;\n" " int j = --x;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void test(int x) {\n" " int i = x--;\n" " int j = x--;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void test(int x) {\n" " int i = x + 1;\n" " int j = 1 + x;\n" "}"); ASSERT_EQUALS("", errout.str()); } void duplicateVarExpressionUnique() { check("struct SW { int first; };\n" "void foo(SW* x) {\n" " int start = x->first;\n" " int end = x->first;\n" "}"); ASSERT_EQUALS("[test.cpp:4] -> [test.cpp:3]: (style, inconclusive) Same expression used in consecutive assignments of 'start' and 'end'.\n" "[test.cpp:2]: (style) Parameter 'x' can be declared as pointer to const\n", errout.str()); check("struct SW { int first; };\n" "void foo(SW* x, int i, int j) {\n" " int start = x->first;\n" " int end = x->first;\n" "}"); ASSERT_EQUALS("[test.cpp:4] -> [test.cpp:3]: (style, inconclusive) Same expression used in consecutive assignments of 'start' and 'end'.\n" "[test.cpp:2]: (style) Parameter 'x' can be declared as pointer to const\n", errout.str()); check("struct Foo { int f() const; };\n" "void test() {\n" " Foo f = Foo{};\n" " int i = f.f();\n" " int j = f.f();\n" "}"); ASSERT_EQUALS("[test.cpp:5] -> [test.cpp:4]: (style, inconclusive) Same expression used in consecutive assignments of 'i' and 'j'.\n", errout.str()); check("void test(const int * p) {\n" " int i = *p;\n" " int j = *p;\n" "}"); ASSERT_EQUALS("[test.cpp:3] -> [test.cpp:2]: (style, inconclusive) Same expression used in consecutive assignments of 'i' and 'j'.\n", errout.str()); check("struct Foo { int f() const; int g(int) const; };\n" "void test() {\n" " Foo f = Foo{};\n" " int i = f.f();\n" " int j = f.f();\n" "}"); ASSERT_EQUALS("[test.cpp:5] -> [test.cpp:4]: (style, inconclusive) Same expression used in consecutive assignments of 'i' and 'j'.\n", errout.str()); check("struct Foo { int f() const; };\n" "void test() {\n" " Foo f = Foo{};\n" " int i = f.f();\n" " int j = f.f();\n" "}"); ASSERT_EQUALS("[test.cpp:5] -> [test.cpp:4]: (style, inconclusive) Same expression used in consecutive assignments of 'i' and 'j'.\n", errout.str()); } void duplicateVarExpressionAssign() { check("struct A { int x; int y; };" "void use(int);\n" "void test(A a) {\n" " int i = a.x;\n" " int j = a.x;\n" " use(i);\n" " i = j;\n" "}"); ASSERT_EQUALS("[test.cpp:4] -> [test.cpp:3]: (style, inconclusive) Same expression used in consecutive assignments of 'i' and 'j'.\n", errout.str()); check("struct A { int x; int y; };" "void use(int);\n" "void test(A a) {\n" " int i = a.x;\n" " int j = a.x;\n" " use(j);\n" " j = i;\n" "}"); ASSERT_EQUALS("[test.cpp:4] -> [test.cpp:3]: (style, inconclusive) Same expression used in consecutive assignments of 'i' and 'j'.\n", errout.str()); check("struct A { int x; int y; };" "void use(int);\n" "void test(A a) {\n" " int i = a.x;\n" " int j = a.x;\n" " use(j);\n" " if (i == j) {}\n" "}"); ASSERT_EQUALS( "[test.cpp:4] -> [test.cpp:3]: (style, inconclusive) Same expression used in consecutive assignments of 'i' and 'j'.\n" "[test.cpp:3] -> [test.cpp:4] -> [test.cpp:6]: (style) The comparison 'i == j' is always true because 'i' and 'j' represent the same value.\n", errout.str()); check("struct A { int x; int y; };" "void use(int);\n" "void test(A a) {\n" " int i = a.x;\n" " int j = a.x;\n" " use(j);\n" " if (i == a.x) {}\n" "}"); ASSERT_EQUALS( "[test.cpp:4] -> [test.cpp:3]: (style, inconclusive) Same expression used in consecutive assignments of 'i' and 'j'.\n" "[test.cpp:3] -> [test.cpp:6]: (style) The comparison 'i == a.x' is always true because 'i' and 'a.x' represent the same value.\n", errout.str()); check("struct A { int x; int y; };" "void use(int);\n" "void test(A a) {\n" " int i = a.x;\n" " int j = a.x;\n" " use(i);\n" " if (j == a.x) {}\n" "}"); ASSERT_EQUALS( "[test.cpp:4] -> [test.cpp:3]: (style, inconclusive) Same expression used in consecutive assignments of 'i' and 'j'.\n" "[test.cpp:4] -> [test.cpp:6]: (style) The comparison 'j == a.x' is always true because 'j' and 'a.x' represent the same value.\n", errout.str()); // Issue #8612 check("struct P\n" "{\n" " void func();\n" " bool operator==(const P&) const;\n" "};\n" "struct X\n" "{\n" " P first;\n" " P second;\n" "};\n" "bool bar();\n" "void baz(const P&);\n" "void foo(const X& x)\n" "{\n" " P current = x.first;\n" " P previous = x.first;\n" " while (true)\n" " {\n" " baz(current);\n" " if (bar() && previous == current)\n" " {\n" " current.func();\n" " }\n" " previous = current;\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:16] -> [test.cpp:15]: (style, inconclusive) Same expression used in consecutive assignments of 'current' and 'previous'.\n", errout.str()); } void duplicateVarExpressionCrash() { // Issue #8624 check("struct X {\n" " X();\n" " int f() const;\n" "};\n" "void run() {\n" " X x;\n" " int a = x.f();\n" " int b = x.f();\n" " (void)a;\n" " (void)b;\n" "}"); ASSERT_EQUALS("[test.cpp:8] -> [test.cpp:7]: (style, inconclusive) Same expression used in consecutive assignments of 'a' and 'b'.\n", errout.str()); // Issue #8712 check("void f() {\n" " unsigned char d;\n" " d = d % 5;\n" "}"); ASSERT_EQUALS("", errout.str()); check("template \n" "T f() {\n" " T x = T();\n" "}\n" "int &a = f();"); ASSERT_EQUALS("", errout.str()); // Issue #8713 check("class A {\n" " int64_t B = 32768;\n" " P m = MakeP(B);\n" "};\n" "void f() {\n" " uint32_t a = 42;\n" " uint32_t b = uint32_t(A ::B / 1024);\n" " int32_t c = int32_t(a / b);\n" "}"); ASSERT_EQUALS("", errout.str()); // Issue #8709 check("a b;\n" "void c() {\n" " switch (d) { case b:; }\n" " double e(b);\n" " if(e <= 0) {}\n" "}"); ASSERT_EQUALS("", errout.str()); // #10718 // Should probably not be inconclusive check("struct a {\n" " int b() const;\n" " auto c() -> decltype(0) {\n" " a d;\n" " int e = d.b(), f = d.b();\n" " return e + f;\n" " }\n" "};\n"); ASSERT_EQUALS("[test.cpp:5] -> [test.cpp:5]: (style, inconclusive) Same expression used in consecutive assignments of 'e' and 'f'.\n", errout.str()); } void multiConditionSameExpression() { check("void f() {\n" " int val = 0;\n" " if (val < 0) continue;\n" " if ((val > 0)) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:3]: (style) The comparison 'val < 0' is always false.\n" "[test.cpp:2] -> [test.cpp:4]: (style) The comparison 'val > 0' is always false.\n", errout.str()); check("void f() {\n" " int val = 0;\n" " int *p = &val;n" " val = 1;\n" " if (*p < 0) continue;\n" " if ((*p > 0)) {}\n" "}\n"); ASSERT_EQUALS("[test.cpp:3]: (style) Variable 'p' can be declared as pointer to const\n", errout.str()); check("void f() {\n" " int val = 0;\n" " int *p = &val;\n" " if (*p < 0) continue;\n" " if ((*p > 0)) {}\n" "}\n"); TODO_ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:3]: (style) The comparison '*p < 0' is always false.\n" "[test.cpp:2] -> [test.cpp:4]: (style) The comparison '*p > 0' is always false.\n", "[test.cpp:3]: (style) Variable 'p' can be declared as pointer to const\n", errout.str()); check("void f() {\n" " int val = 0;\n" " if (val < 0) {\n" " if ((val > 0)) {}\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:3]: (style) The comparison 'val < 0' is always false.\n" "[test.cpp:2] -> [test.cpp:4]: (style) The comparison 'val > 0' is always false.\n", errout.str()); check("void f() {\n" " int val = 0;\n" " if (val < 0) {\n" " if ((val < 0)) {}\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:3]: (style) The comparison 'val < 0' is always false.\n" "[test.cpp:2] -> [test.cpp:4]: (style) The comparison 'val < 0' is always false.\n", errout.str()); check("void f() {\n" " int activate = 0;\n" " int foo = 0;\n" " if (activate) {}\n" " else if (foo) {}\n" "}"); ASSERT_EQUALS("", errout.str()); } void checkSignOfUnsignedVariable() { check("void foo() {\n" " for(unsigned char i = 10; i >= 0; i--) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Unsigned expression 'i' can't be negative so it is unnecessary to test it.\n", errout.str()); check("void foo(bool b) {\n" " for(unsigned int i = 10; b || i >= 0; i--) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Unsigned expression 'i' can't be negative so it is unnecessary to test it.\n", errout.str()); { const char code[] = "void foo(unsigned int x) {\n" " if (x < 0) {}\n" "}"; check(code, nullptr, false, true, false); ASSERT_EQUALS("[test.cpp:2]: (style) Checking if unsigned expression 'x' is less than zero.\n", errout.str()); check(code, nullptr, false, true, true); ASSERT_EQUALS("[test.cpp:2]: (style) Checking if unsigned expression 'x' is less than zero.\n", errout.str()); } check("void foo(unsigned int x) {\n" " if (x < 0u) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Checking if unsigned expression 'x' is less than zero.\n", errout.str()); check("void foo(int x) {\n" " if (x < 0) {}\n" "}"); ASSERT_EQUALS("", errout.str()); { const char code[] = "void foo(unsigned x) {\n" " int y = 0;\n" " if (x < y) {}\n" "}"; check(code, nullptr, false, true, false); ASSERT_EQUALS("[test.cpp:3]: (style) Checking if unsigned expression 'x' is less than zero.\n", errout.str()); check(code, nullptr, false, true, true); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:3]: (style) Checking if unsigned expression 'x' is less than zero.\n", errout.str()); } check("void foo(unsigned x) {\n" " int y = 0;\n" " if (b)\n" " y = 1;\n" " if (x < y) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(unsigned int x) {\n" " if (0 > x) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Checking if unsigned expression 'x' is less than zero.\n", errout.str()); check("void foo(unsigned int x) {\n" " if (0UL > x) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Checking if unsigned expression 'x' is less than zero.\n", errout.str()); check("void foo(int x) {\n" " if (0 > x) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(unsigned int x) {\n" " if (x >= 0) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Unsigned expression 'x' can't be negative so it is unnecessary to test it.\n", errout.str()); check("void foo(unsigned int x, unsigned y) {\n" " if (x - y >= 0) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Unsigned expression 'x-y' can't be negative so it is unnecessary to test it.\n", errout.str()); check("void foo(unsigned int x) {\n" " if (x >= 0ull) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Unsigned expression 'x' can't be negative so it is unnecessary to test it.\n", errout.str()); check("void foo(int x) {\n" " if (x >= 0) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(unsigned int x) {\n" " if (0 <= x) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Unsigned expression 'x' can't be negative so it is unnecessary to test it.\n", errout.str()); check("void foo(unsigned int x) {\n" " if (0ll <= x) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Unsigned expression 'x' can't be negative so it is unnecessary to test it.\n", errout.str()); check("void foo(int x) {\n" " if (0 <= x) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(unsigned int x, bool y) {\n" " if (x < 0 && y) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Checking if unsigned expression 'x' is less than zero.\n", errout.str()); check("void foo(int x, bool y) {\n" " if (x < 0 && y) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(unsigned int x, bool y) {\n" " if (0 > x && y) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Checking if unsigned expression 'x' is less than zero.\n", errout.str()); check("void foo(int x, bool y) {\n" " if (0 > x && y) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(unsigned int x, bool y) {\n" " if (x >= 0 && y) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Unsigned expression 'x' can't be negative so it is unnecessary to test it.\n", errout.str()); check("void foo(int x, bool y) {\n" " if (x >= 0 && y) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(unsigned int x, bool y) {\n" " if (y && x < 0) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Checking if unsigned expression 'x' is less than zero.\n", errout.str()); check("void foo(int x, bool y) {\n" " if (y && x < 0) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(unsigned int x, bool y) {\n" " if (y && 0 > x) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Checking if unsigned expression 'x' is less than zero.\n", errout.str()); check("void foo(int x, bool y) {\n" " if (y && 0 > x) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(unsigned int x, bool y) {\n" " if (y && x >= 0) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Unsigned expression 'x' can't be negative so it is unnecessary to test it.\n", errout.str()); check("void foo(int x, bool y) {\n" " if (y && x >= 0) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(unsigned int x, bool y) {\n" " if (x < 0 || y) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Checking if unsigned expression 'x' is less than zero.\n", errout.str()); check("void foo(int x, bool y) {\n" " if (x < 0 || y) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(unsigned int x, bool y) {\n" " if (0 > x || y) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Checking if unsigned expression 'x' is less than zero.\n", errout.str()); check("void foo(int x, bool y) {\n" " if (0 > x || y) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(unsigned int x, bool y) {\n" " if (x >= 0 || y) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Unsigned expression 'x' can't be negative so it is unnecessary to test it.\n", errout.str()); check("void foo(int x, bool y) {\n" " if (x >= 0 || y) {}\n" "}"); ASSERT_EQUALS("", errout.str()); // #3233 - FP when template is used (template parameter is numeric constant) { const char code[] = "template void foo(unsigned int x) {\n" " if (x <= n);\n" "}\n" "foo<0>();"; check(code, nullptr, false); ASSERT_EQUALS("", errout.str()); check(code, nullptr, true); ASSERT_EQUALS("", errout.str()); } { Settings s = settingsBuilder().checkUnusedTemplates().build(); check("template void foo(unsigned int x) {\n" "if (x <= 0);\n" "}", &s); ASSERT_EQUALS("[test.cpp:2]: (style) Checking if unsigned expression 'x' is less than zero.\n", errout.str()); } // #8836 check("uint32_t value = 0xFUL;\n" "void f() {\n" " if (value < 0u)\n" " {\n" " value = 0u;\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (style) Checking if unsigned expression 'value' is less than zero.\n", errout.str()); // #9040 Settings settings1 = settingsBuilder().platform(cppcheck::Platform::Type::Win64).build(); check("using BOOL = unsigned;\n" "int i;\n" "bool f() {\n" " return i >= 0;\n" "}\n", &settings1); ASSERT_EQUALS("", errout.str()); // #10612 check("void f(void) {\n" " const uint32_t x = 0;\n" " constexpr const auto y = 0xFFFFU;\n" " if (y < x) {}\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (style) Checking if unsigned expression 'y' is less than zero.\n", errout.str()); } void checkSignOfPointer() { check("void foo(const int* x) {\n" " if (x >= 0) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) A pointer can not be negative so it is either pointless or an error to check if it is not.\n", errout.str()); { const char code[] = "void foo(const int* x) {\n" " int y = 0;\n" " if (x >= y) {}\n" "}"; check(code, nullptr, false, true, false); ASSERT_EQUALS("[test.cpp:3]: (style) A pointer can not be negative so it is either pointless or an error to check if it is not.\n", errout.str()); check(code, nullptr, false, true, true); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:3]: (style) A pointer can not be negative so it is either pointless or an error to check if it is not.\n", errout.str()); } check("void foo(const int* x) {\n" " if (*x >= 0) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(const int* x) {\n" " if (x < 0) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) A pointer can not be negative so it is either pointless or an error to check if it is.\n", errout.str()); { const char code[] = "void foo(const int* x) {\n" " unsigned y = 0u;\n" " if (x < y) {}\n" "}"; check(code, nullptr, false, true, false); ASSERT_EQUALS("[test.cpp:3]: (style) A pointer can not be negative so it is either pointless or an error to check if it is.\n", errout.str()); check(code, nullptr, false, true, true); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:3]: (style) A pointer can not be negative so it is either pointless or an error to check if it is.\n", errout.str()); } check("void foo(const int* x) {\n" " if (*x < 0) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(const int* x, const int* y) {\n" " if (x - y < 0) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(const int* x, const int* y) {\n" " if (x - y <= 0) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(const int* x, const int* y) {\n" " if (x - y > 0) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(const int* x, const int* y) {\n" " if (x - y >= 0) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(const Bar* x) {\n" " if (0 <= x) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) A pointer can not be negative so it is either pointless or an error to check if it is not.\n", errout.str()); check("struct S {\n" " int* ptr;\n" "};\n" "void foo(S* first) {\n" " if (first.ptr >= 0) {}\n" "}"); ASSERT_EQUALS("[test.cpp:5]: (style) A pointer can not be negative so it is either pointless or an error to check if it is not.\n" "[test.cpp:4]: (style) Parameter 'first' can be declared as pointer to const\n", errout.str()); check("struct S {\n" " int* ptr;\n" "};\n" "void foo(S* first, S* second) {\n" " if((first.ptr - second.ptr) >= 0) {}\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (style) Parameter 'first' can be declared as pointer to const\n" "[test.cpp:4]: (style) Parameter 'second' can be declared as pointer to const\n", errout.str()); check("struct S {\n" " int* ptr;\n" "};\n" "void foo(S* first) {\n" " if((first.ptr) >= 0) {}\n" "}"); ASSERT_EQUALS("[test.cpp:5]: (style) A pointer can not be negative so it is either pointless or an error to check if it is not.\n" "[test.cpp:4]: (style) Parameter 'first' can be declared as pointer to const\n", errout.str()); check("struct S {\n" " int* ptr;\n" "};\n" "void foo(S* first, S* second) {\n" " if(0 <= first.ptr - second.ptr) {}\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (style) Parameter 'first' can be declared as pointer to const\n" "[test.cpp:4]: (style) Parameter 'second' can be declared as pointer to const\n", errout.str()); check("struct S {\n" " int* ptr;\n" "};\n" "void foo(S* first, S* second) {\n" " if(0 <= (first.ptr - second.ptr)) {}\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (style) Parameter 'first' can be declared as pointer to const\n" "[test.cpp:4]: (style) Parameter 'second' can be declared as pointer to const\n", errout.str()); check("struct S {\n" " int* ptr;\n" "};\n" "void foo(S* first, S* second) {\n" " if(first.ptr - second.ptr < 0) {}\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (style) Parameter 'first' can be declared as pointer to const\n" "[test.cpp:4]: (style) Parameter 'second' can be declared as pointer to const\n", errout.str()); check("struct S {\n" " int* ptr;\n" "};\n" "void foo(S* first, S* second) {\n" " if((first.ptr - second.ptr) < 0) {}\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (style) Parameter 'first' can be declared as pointer to const\n" "[test.cpp:4]: (style) Parameter 'second' can be declared as pointer to const\n", errout.str()); check("struct S {\n" " int* ptr;\n" "};\n" "void foo(S* first, S* second) {\n" " if(0 > first.ptr - second.ptr) {}\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (style) Parameter 'first' can be declared as pointer to const\n" "[test.cpp:4]: (style) Parameter 'second' can be declared as pointer to const\n", errout.str()); check("struct S {\n" " int* ptr;\n" "};\n" "void foo(S* first, S* second) {\n" " if(0 > (first.ptr - second.ptr)) {}\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (style) Parameter 'first' can be declared as pointer to const\n" "[test.cpp:4]: (style) Parameter 'second' can be declared as pointer to const\n", errout.str()); check("void foo(const int* x) {\n" " if (0 <= x[0]) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(Bar* x) {\n" " if (0 <= x.y) {}\n" "}"); ASSERT_EQUALS("[test.cpp:1]: (style) Parameter 'x' can be declared as pointer to const\n", errout.str()); check("void foo(Bar* x) {\n" " if (0 <= x->y) {}\n" "}"); ASSERT_EQUALS("[test.cpp:1]: (style) Parameter 'x' can be declared as pointer to const\n", errout.str()); check("void foo(Bar* x, Bar* y) {\n" " if (0 <= x->y - y->y ) {}\n" "}"); ASSERT_EQUALS("[test.cpp:1]: (style) Parameter 'x' can be declared as pointer to const\n" "[test.cpp:1]: (style) Parameter 'y' can be declared as pointer to const\n", errout.str()); check("void foo(const Bar* x) {\n" " if (0 > x) {}\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) A pointer can not be negative so it is either pointless or an error to check if it is.\n", errout.str()); check("void foo(const int* x) {\n" " if (0 > x[0]) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(Bar* x) {\n" " if (0 > x.y) {}\n" "}"); ASSERT_EQUALS("[test.cpp:1]: (style) Parameter 'x' can be declared as pointer to const\n", errout.str()); check("void foo(Bar* x) {\n" " if (0 > x->y) {}\n" "}"); ASSERT_EQUALS("[test.cpp:1]: (style) Parameter 'x' can be declared as pointer to const\n", errout.str()); check("void foo() {\n" " int (*t)(void *a, void *b);\n" " if (t(a, b) < 0) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo() {\n" " int (*t)(void *a, void *b);\n" " if (0 > t(a, b)) {}\n" "}"); ASSERT_EQUALS("", errout.str()); check("struct object_info { int *typep; };\n" "void packed_object_info(struct object_info *oi) {\n" " if (oi->typep < 0);\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (style) A pointer can not be negative so it is either pointless or an error to check if it is.\n" "[test.cpp:2]: (style) Parameter 'oi' can be declared as pointer to const\n", errout.str()); check("struct object_info { int typep[10]; };\n" "void packed_object_info(struct object_info *oi) {\n" " if (oi->typep < 0);\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (style) A pointer can not be negative so it is either pointless or an error to check if it is.\n" "[test.cpp:2]: (style) Parameter 'oi' can be declared as pointer to const\n", errout.str()); check("struct object_info { int *typep; };\n" "void packed_object_info(struct object_info *oi) {\n" " if (*oi->typep < 0);\n" "}"); ASSERT_EQUALS("", errout.str()); } void checkSuspiciousSemicolon1() { check("void foo() {\n" " for(int i = 0; i < 10; ++i);\n" "}"); ASSERT_EQUALS("", errout.str()); // Empty block check("void foo() {\n" " for(int i = 0; i < 10; ++i); {\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (warning) Suspicious use of ; at the end of 'for' statement.\n", errout.str()); check("void foo() {\n" " while (!quit); {\n" " do_something();\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (warning) Suspicious use of ; at the end of 'while' statement.\n", errout.str()); } void checkSuspiciousSemicolon2() { check("void foo() {\n" " if (i == 1); {\n" " do_something();\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (warning) Suspicious use of ; at the end of 'if' statement.\n", errout.str()); // Seen this in the wild check("void foo() {\n" " if (Match());\n" " do_something();\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo() {\n" " if (Match());\n" " else\n" " do_something();\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo() {\n" " if (i == 1)\n" " ;\n" " {\n" " do_something();\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo() {\n" " if (i == 1);\n" "\n" " {\n" " do_something();\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); } void checkSuspiciousSemicolon3() { checkP("#define REQUIRE(code) {code}\n" "void foo() {\n" " if (x == 123);\n" " REQUIRE(y=z);\n" "}"); ASSERT_EQUALS("", errout.str()); } void checkSuspiciousComparison() { checkP("void f(int a, int b) {\n" " a > b;\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (warning, inconclusive) Found suspicious operator '>', result is not used.\n", errout.str()); checkP("void f() {\n" // #10607 " for (auto p : m)\n" " std::vector> k;\n" "}"); ASSERT_EQUALS("", errout.str()); } void checkInvalidFree() { check("void foo(char *p) {\n" " char *a; a = malloc(1024);\n" " free(a + 10);\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (error) Mismatching address is freed. The address you get from malloc() must be freed without offset.\n", errout.str()); check("void foo(char *p) {\n" " char *a; a = malloc(1024);\n" " free(a - 10);\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (error) Mismatching address is freed. The address you get from malloc() must be freed without offset.\n", errout.str()); check("void foo(char *p) {\n" " char *a; a = malloc(1024);\n" " free(10 + a);\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (error) Mismatching address is freed. The address you get from malloc() must be freed without offset.\n", errout.str()); check("void foo(char *p) {\n" " char *a; a = new char[1024];\n" " delete[] (a + 10);\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (error) Mismatching address is deleted. The address you get from new must be deleted without offset.\n", errout.str()); check("void foo(char *p) {\n" " char *a; a = new char;\n" " delete a + 10;\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (error) Mismatching address is deleted. The address you get from new must be deleted without offset.\n", errout.str()); check("void foo(char *p) {\n" " char *a; a = new char;\n" " bar(a);\n" " delete a + 10;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(char *p) {\n" " char *a; a = new char;\n" " char *b; b = new char;\n" " bar(a);\n" " delete a + 10;\n" " delete b + 10;\n" "}"); ASSERT_EQUALS("[test.cpp:6]: (error) Mismatching address is deleted. The address you get from new must be deleted without offset.\n", errout.str()); check("void foo(char *p) {\n" " char *a; a = new char;\n" " char *b; b = new char;\n" " bar(a, b);\n" " delete a + 10;\n" " delete b + 10;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(char *p) {\n" " char *a; a = new char;\n" " bar()\n" " delete a + 10;\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (error) Mismatching address is deleted. The address you get from new must be deleted without offset.\n", errout.str()); check("void foo(size_t xx) {\n" " char *ptr; ptr = malloc(42);\n" " ptr += xx;\n" " free(ptr + 1 - xx);\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (error) Mismatching address is freed. The address you get from malloc() must be freed without offset.\n", errout.str()); check("void foo(size_t xx) {\n" " char *ptr; ptr = malloc(42);\n" " std::cout << ptr;\n" " ptr = otherPtr;\n" " free(otherPtr - xx - 1);\n" "}"); ASSERT_EQUALS("", errout.str()); } void checkRedundantCopy() { check("const std::string& getA(){static std::string a;return a;}\n" "void foo() {\n" " const std::string a = getA();\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (performance, inconclusive) Use const reference for 'a' to avoid unnecessary data copying.\n", errout.str()); check("class A{public:A(){}};\n" "const A& getA(){static A a;return a;}\n" "int main()\n" "{\n" " const A a = getA();\n" " return 0;\n" "}"); ASSERT_EQUALS("[test.cpp:5]: (performance, inconclusive) Use const reference for 'a' to avoid unnecessary data copying.\n", errout.str()); check("const int& getA(){static int a;return a;}\n" "int main()\n" "{\n" " const int a = getA();\n" " return 0;\n" "}"); ASSERT_EQUALS("", errout.str()); check("const int& getA(){static int a;return a;}\n" "int main()\n" "{\n" " int getA = 0;\n" " const int a = getA + 3;\n" " return 0;\n" "}"); ASSERT_EQUALS("[test.cpp:1] -> [test.cpp:4]: (style) Local variable \'getA\' shadows outer function\n", errout.str()); check("class A{public:A(){}};\n" "const A& getA(){static A a;return a;}\n" "int main()\n" "{\n" " const A a(getA());\n" " return 0;\n" "}"); ASSERT_EQUALS("[test.cpp:5]: (performance, inconclusive) Use const reference for 'a' to avoid unnecessary data copying.\n", errout.str()); check("const int& getA(){static int a;return a;}\n" "int main()\n" "{\n" " const int a(getA());\n" " return 0;\n" "}"); ASSERT_EQUALS("", errout.str()); check("class A{\n" "public:A(int a=0){_a = a;}\n" "A operator+(const A & a){return A(_a+a._a);}\n" "private:int _a;};\n" "const A& getA(){static A a;return a;}\n" "int main()\n" "{\n" " const A a = getA() + 1;\n" " return 0;\n" "}"); ASSERT_EQUALS("", errout.str()); check("class A{\n" "public:A(int a=0){_a = a;}\n" "A operator+(const A & a){return A(_a+a._a);}\n" "private:int _a;};\n" "const A& getA(){static A a;return a;}\n" "int main()\n" "{\n" " const A a(getA()+1);\n" " return 0;\n" "}"); ASSERT_EQUALS("", errout.str()); // #5190 - FP when creating object with constructor that takes a reference check("class A {};\n" "class B { B(const A &a); };\n" "const A &getA();\n" "void f() {\n" " const B b(getA());\n" "}"); ASSERT_EQUALS("", errout.str()); check("class A {};\n" "class B { B(const A& a); };\n" "const A& getA();\n" "void f() {\n" " const B b{ getA() };\n" "}"); ASSERT_EQUALS("", errout.str()); // #5618 const char* code5618 = "class Token {\n" "public:\n" " const std::string& str();\n" "};\n" "void simplifyArrayAccessSyntax() {\n" " for (Token *tok = list.front(); tok; tok = tok->next()) {\n" " const std::string temp = tok->str();\n" " tok->str(tok->strAt(2));\n" " }\n" "}"; check(code5618, nullptr, true); ASSERT_EQUALS("", errout.str()); check(code5618, nullptr, false); ASSERT_EQUALS("", errout.str()); // #5890 - crash: wesnoth desktop_util.cpp / unicode.hpp check("typedef std::vector X;\n" "X f(const X &in) {\n" " const X s = f(in);\n" " return f(s);\n" "}"); ASSERT_EQUALS("", errout.str()); // #7981 - False positive redundantCopyLocalConst - const ref argument to ctor check("class CD {\n" " public:\n" " CD(const CD&);\n" " static const CD& getOne();\n" "};\n" " \n" "void foo() {\n" " const CD cd(CD::getOne());\n" "}", nullptr, true); ASSERT_EQUALS("", errout.str()); check("struct S {\n" // #10545 " int modify();\n" " const std::string& get() const;\n" "};\n" "std::string f(S& s) {\n" " const std::string old = s.get();\n" " int i = s.modify();\n" " if (i != 0)\n" " return old;\n" " return {};\n" "}", nullptr, /*inconclusive*/ true); ASSERT_EQUALS("", errout.str()); check("struct X { int x; };\n" // #10191 "struct S {\n" " X _x;\n" " X& get() { return _x; }\n" " void modify() { _x.x += 42; }\n" " int copy() {\n" " const X x = get();\n" " modify();\n" " return x.x;\n" " }\n" " int constref() {\n" " const X& x = get();\n" " modify();\n" " return x.x;\n" " }\n" "};\n", nullptr, /*inconclusive*/ true); ASSERT_EQUALS("", errout.str()); // #10704 check("struct C {\n" " std::string str;\n" " const std::string& get() const { return str; }\n" "};\n" "struct D {\n" " C c;\n" " bool f() const {\n" " std::string s = c.get();\n" " return s.empty();\n" " }\n" "};\n"); ASSERT_EQUALS("[test.cpp:8]: (performance, inconclusive) Use const reference for 's' to avoid unnecessary data copying.\n", errout.str()); check("struct C {\n" " const std::string & get() const { return m; }\n" " std::string m;\n" "};\n" "C getC();\n" "void f() {\n" " const std::string s = getC().get();\n" "}\n" "void g() {\n" " std::string s = getC().get();\n" "}\n"); ASSERT_EQUALS("", errout.str()); } void checkNegativeShift() { check("void foo()\n" "{\n" " int a; a = 123;\n" " (void)(a << -1);\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (error) Shifting by a negative value is undefined behaviour\n", errout.str()); check("void foo()\n" "{\n" " int a; a = 123;\n" " (void)(a >> -1);\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (error) Shifting by a negative value is undefined behaviour\n", errout.str()); check("void foo()\n" "{\n" " int a; a = 123;\n" " a <<= -1;\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (error) Shifting by a negative value is undefined behaviour\n", errout.str()); check("void foo()\n" "{\n" " int a; a = 123;\n" " a >>= -1;\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (error) Shifting by a negative value is undefined behaviour\n", errout.str()); check("void foo()\n" "{\n" " std::cout << -1;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo()\n" "{\n" " std::cout << a << -1 ;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo()\n" "{\n" " std::cout << 3 << -1 ;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo() {\n" " x = (-10+2) << 3;\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (portability) Shifting a negative value is technically undefined behaviour\n", errout.str()); check("x = y ? z << $-1 : 0;"); ASSERT_EQUALS("", errout.str()); // Negative LHS check("const int x = -1 >> 2;"); ASSERT_EQUALS("[test.cpp:1]: (portability) Shifting a negative value is technically undefined behaviour\n", errout.str()); // #6383 - unsigned type check("const int x = (unsigned int)(-1) >> 2;"); ASSERT_EQUALS("", errout.str()); // #7814 - UB happening in valueflowcode when it tried to compute shifts. check("int shift1() { return 1 >> -1 ;}\n" "int shift2() { return 1 << -1 ;}\n" "int shift3() { return -1 >> 1 ;}\n" "int shift4() { return -1 << 1 ;}"); ASSERT_EQUALS("[test.cpp:1]: (error) Shifting by a negative value is undefined behaviour\n" "[test.cpp:2]: (error) Shifting by a negative value is undefined behaviour\n" "[test.cpp:3]: (portability) Shifting a negative value is technically undefined behaviour\n" "[test.cpp:4]: (portability) Shifting a negative value is technically undefined behaviour\n", errout.str()); } void incompleteArrayFill() { check("void f() {\n" " int a[5];\n" " memset(a, 123, 5);\n" " memcpy(a, b, 5);\n" " memmove(a, b, 5);\n" "}"); ASSERT_EQUALS(// TODO "[test.cpp:4] -> [test.cpp:5]: (performance) Buffer 'a' is being written before its old content has been used.\n" "[test.cpp:3]: (warning, inconclusive) Array 'a' is filled incompletely. Did you forget to multiply the size given to 'memset()' with 'sizeof(*a)'?\n" "[test.cpp:4]: (warning, inconclusive) Array 'a' is filled incompletely. Did you forget to multiply the size given to 'memcpy()' with 'sizeof(*a)'?\n" "[test.cpp:5]: (warning, inconclusive) Array 'a' is filled incompletely. Did you forget to multiply the size given to 'memmove()' with 'sizeof(*a)'?\n", errout.str()); check("int a[5];\n" "namespace Z { struct B { int a[5]; } b; }\n" "void f() {\n" " memset(::a, 123, 5);\n" " memset(Z::b.a, 123, 5);\n" "}"); TODO_ASSERT_EQUALS("[test.cpp:4]: (warning, inconclusive) Array '::a' is filled incompletely. Did you forget to multiply the size given to 'memset()' with 'sizeof(*::a)'?\n" "[test.cpp:5]: (warning, inconclusive) Array 'Z::b.a' is filled incompletely. Did you forget to multiply the size given to 'memset()' with 'sizeof(*Z::b.a)'?\n", "[test.cpp:4]: (warning, inconclusive) Array '::a' is filled incompletely. Did you forget to multiply the size given to 'memset()' with 'sizeof(*::a)'?\n", errout.str()); check("void f() {\n" " Foo* a[5];\n" " memset(a, 'a', 5);\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (warning, inconclusive) Array 'a' is filled incompletely. Did you forget to multiply the size given to 'memset()' with 'sizeof(*a)'?\n", errout.str()); check("class Foo {int a; int b;};\n" "void f() {\n" " Foo a[5];\n" " memset(a, 'a', 5);\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (warning, inconclusive) Array 'a' is filled incompletely. Did you forget to multiply the size given to 'memset()' with 'sizeof(*a)'?\n", errout.str()); check("void f() {\n" " Foo a[5];\n" // Size of foo is unknown " memset(a, 'a', 5);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " char a[5];\n" " memset(a, 'a', 5);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " int a[5];\n" " memset(a+15, 'a', 5);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " bool a[5];\n" " memset(a, false, 5);\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (portability, inconclusive) Array 'a' might be filled incompletely. Did you forget to multiply the size given to 'memset()' with 'sizeof(*a)'?\n", errout.str()); } void redundantVarAssignment() { setMultiline(); // Simple tests check("void f(int i) {\n" " i = 1;\n" " i = 1;\n" "}"); ASSERT_EQUALS("test.cpp:3:style:Variable 'i' is reassigned a value before the old one has been used.\n" "test.cpp:2:note:i is assigned\n" "test.cpp:3:note:i is overwritten\n", errout.str()); // non-local variable => only show warning when inconclusive is used check("int i;\n" "void f() {\n" " i = 1;\n" " i = 1;\n" "}"); ASSERT_EQUALS("test.cpp:4:style:Variable 'i' is reassigned a value before the old one has been used.\n" "test.cpp:3:note:i is assigned\n" "test.cpp:4:note:i is overwritten\n", errout.str()); check("void f() {\n" " int i;\n" " i = 1;\n" " i = 1;\n" "}"); ASSERT_EQUALS("test.cpp:4:style:Variable 'i' is reassigned a value before the old one has been used.\n" "test.cpp:3:note:i is assigned\n" "test.cpp:4:note:i is overwritten\n", errout.str()); check("void f() {\n" " static int i;\n" " i = 1;\n" " i = 1;\n" "}"); TODO_ASSERT_EQUALS("error", "", errout.str()); check("void f() {\n" " int i[10];\n" " i[2] = 1;\n" " i[2] = 1;\n" "}"); ASSERT_EQUALS("test.cpp:4:style:Variable 'i[2]' is reassigned a value before the old one has been used.\n" "test.cpp:3:note:i[2] is assigned\n" "test.cpp:4:note:i[2] is overwritten\n", errout.str()); check("void f(int x) {\n" " int i[10];\n" " i[x] = 1;\n" " x=1;\n" " i[x] = 1;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(const int x) {\n" " int i[10];\n" " i[x] = 1;\n" " i[x] = 1;\n" "}"); ASSERT_EQUALS("test.cpp:4:style:Variable 'i[x]' is reassigned a value before the old one has been used.\n" "test.cpp:3:note:i[x] is assigned\n" "test.cpp:4:note:i[x] is overwritten\n", errout.str()); // Testing different types check("void f() {\n" " Foo& bar = foo();\n" " bar = x;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " Foo& bar = foo();\n" " bar = x;\n" " bar = y;\n" "}"); TODO_ASSERT_EQUALS("error", "", errout.str()); check("void f() {\n" " Foo& bar = foo();\n" // #4425. bar might refer to something global, etc. " bar = y();\n" " foo();\n" " bar = y();\n" "}"); ASSERT_EQUALS("", errout.str()); // Tests with function call between assignment check("void f(int i) {\n" " i = 1;\n" " bar();\n" " i = 1;\n" "}"); ASSERT_EQUALS("test.cpp:4:style:Variable 'i' is reassigned a value before the old one has been used.\n" "test.cpp:2:note:i is assigned\n" "test.cpp:4:note:i is overwritten\n", errout.str()); check("int i;\n" "void f() {\n" " i = 1;\n" " bar();\n" // Global variable might be accessed in bar() " i = 1;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " static int i;\n" " i = 1;\n" " bar();\n" // bar() might call f() recursively. This could be a false positive in more complex examples (when value of i is used somewhere. See #4229) " i = 2;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " int i;\n" " i = 1;\n" " bar();\n" " i = 1;\n" "}"); ASSERT_EQUALS("test.cpp:5:style:Variable 'i' is reassigned a value before the old one has been used.\n" "test.cpp:3:note:i is assigned\n" "test.cpp:5:note:i is overwritten\n", errout.str()); check("void bar(int i) {}\n" "void f(int i) {\n" " i = 1;\n" " bar(i);\n" // Passed as argument " i = 1;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " Foo bar = foo();\n" " bar();\n" // #5568. operator() called " bar = y();\n" "}"); ASSERT_EQUALS("", errout.str()); // Branch tests check("void f(int i) {\n" " i = 1;\n" " if(x)\n" " i = 0;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(int i) {\n" " if(x)\n" " i = 0;\n" " i = 1;\n" " i = 2;\n" "}"); ASSERT_EQUALS("test.cpp:5:style:Variable 'i' is reassigned a value before the old one has been used.\n" "test.cpp:4:note:i is assigned\n" "test.cpp:5:note:i is overwritten\n", errout.str()); // #4513 check("int x;\n" "int g() {\n" " return x*x;\n" "}\n" "void f() {\n" " x = 2;\n" " x = g();\n" "}"); ASSERT_EQUALS("", errout.str()); check("int g() {\n" " return x*x;\n" "}\n" "void f(int x) {\n" " x = 2;\n" " x = g();\n" "}"); ASSERT_EQUALS("test.cpp:6:style:Variable 'x' is reassigned a value before the old one has been used.\n" "test.cpp:5:note:x is assigned\n" "test.cpp:6:note:x is overwritten\n", errout.str()); check("void f() {\n" " Foo& bar = foo();\n" " bar = x;\n" " bar = y();\n" "}"); ASSERT_EQUALS("", errout.str()); check("class C {\n" " int x;\n" " void g() { return x * x; }\n" " void f();\n" "};\n" "\n" "void C::f() {\n" " x = 2;\n" " x = g();\n" "}"); ASSERT_EQUALS("", errout.str()); check("class C {\n" " int x;\n" " void g() { return x*x; }\n" " void f(Foo z);\n" "};\n" "\n" "void C::f(Foo z) {\n" " x = 2;\n" " x = z.g();\n" "}"); ASSERT_EQUALS("", errout.str()); // ({ }) check("void f() {\n" " int x;\n" " x = 321;\n" " x = ({ asm(123); })\n" "}"); ASSERT_EQUALS("", errout.str()); // from #3103 (avoid a false negative) check("int foo(){\n" " int x;\n" " x = 1;\n" " x = 1;\n" " return x + 1;\n" "}"); ASSERT_EQUALS("test.cpp:4:style:Variable 'x' is reassigned a value before the old one has been used.\n" "test.cpp:3:note:x is assigned\n" "test.cpp:4:note:x is overwritten\n", errout.str()); // from #3103 (avoid a false positive) check("int foo(){\n" " int x;\n" " x = 1;\n" " if (y)\n" // <-- cppcheck does not know anything about 'y' " x = 2;\n" " return x + 1;\n" "}"); ASSERT_EQUALS("", errout.str()); // initialization, assignment with 0 check("void f() {\n" // Ticket #4356 " int x = 0;\n" // <- ignore initialization with 0 " x = 3;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " state_t *x = NULL;\n" " x = dostuff();\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " state_t *x;\n" " x = NULL;\n" " x = dostuff();\n" "}"); ASSERT_EQUALS("", errout.str()); check("int foo() {\n" // #4420 " int x;\n" " bar(++x);\n" " x = 5;\n" " return bar(x);\n" "}"); ASSERT_EQUALS("", errout.str()); // struct member.. check("struct AB { int a; int b; };\n" "\n" "int f() {\n" " struct AB ab;\n" " ab.a = 1;\n" " ab.a = 2;\n" " return ab.a;\n" "}"); ASSERT_EQUALS("test.cpp:6:style:Variable 'ab.a' is reassigned a value before the old one has been used.\n" "test.cpp:5:note:ab.a is assigned\n" "test.cpp:6:note:ab.a is overwritten\n", errout.str()); check("struct AB { int a; int b; };\n" "\n" "int f() {\n" " struct AB ab;\n" " ab.a = 1;\n" " ab = do_something();\n" " return ab.a;\n" "}"); TODO_ASSERT_EQUALS("error", "", errout.str()); check("struct AB { int a; int b; };\n" "\n" "int f() {\n" " struct AB ab;\n" " ab.a = 1;\n" " do_something(&ab);\n" " ab.a = 2;\n" " return ab.a;\n" "}"); ASSERT_EQUALS("", errout.str()); check("struct AB { int a; int b; };\n" "\n" "int f(DO_SOMETHING do_something) {\n" " struct AB ab;\n" " ab.a = 1;\n" " do_something(&ab);\n" " ab.a = 2;\n" " return ab.a;\n" "}"); ASSERT_EQUALS("", errout.str()); check("struct AB { int a; int b; };\n" "\n" "int f(struct AB *ab) {\n" " ab->a = 1;\n" " ab->b = 2;\n" " ab++;\n" " ab->a = 1;\n" " ab->b = 2;\n" "}"); ASSERT_EQUALS("", errout.str()); check("struct AB { int a; int b; };\n" "\n" "int f(struct AB *ab) {\n" " ab->a = 1;\n" " ab->b = 2;\n" " ab = x;\n" " ab->a = 1;\n" " ab->b = 2;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(struct AB *ab) {\n" // # " ab->data->x = 1;\n" " ab = &ab1;\n" " ab->data->x = 2;\n" "}"); ASSERT_EQUALS("", errout.str()); // #5964 check("void func(char *buffer, const char *format, int precision, unsigned value) {\n" " (precision < 0) ? sprintf(buffer, format, value) : sprintf(buffer, format, precision, value);\n" "}"); ASSERT_EQUALS("", errout.str()); // don't crash check("struct data {\n" " struct { int i; } fc;\n" "};\n" "struct state {\n" " struct data d[123];\n" "};\n" "void func(struct state *s) {\n" " s->foo[s->x++] = 2;\n" " s->d[1].fc.i++;\n" "}"); // #6525 - inline assembly check("void f(int i) {\n" " i = 1;\n" " asm(\"foo\");\n" " i = 1;\n" "}"); ASSERT_EQUALS("", errout.str()); // #6555 check("void foo() {\n" " char *p = 0;\n" " try {\n" " p = fred();\n" " p = wilma();\n" " }\n" " catch (...) {\n" " barney(p);\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo() {\n" " char *p = 0;\n" " try {\n" " p = fred();\n" " p = wilma();\n" " }\n" " catch (...) {\n" " barney(x);\n" " }\n" "}"); ASSERT_EQUALS("test.cpp:2:style:The scope of the variable 'p' can be reduced.\n", errout.str()); check("void foo() {\n" " char *p = 0;\n" " try {\n" " if(z) {\n" " p = fred();\n" " p = wilma();\n" " }\n" " }\n" " catch (...) {\n" " barney(p);\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); // Member variable pointers check("void podMemPtrs() {\n" " int POD::*memptr;\n" " memptr = &POD::a;\n" " memptr = &POD::b;\n" " if (memptr)\n" " memptr = 0;\n" "}"); ASSERT_EQUALS("test.cpp:4:style:Variable 'memptr' is reassigned a value before the old one has been used.\n" "test.cpp:3:note:memptr is assigned\n" "test.cpp:4:note:memptr is overwritten\n", errout.str()); // Pointer function argument (#3857) check("void f(float * var)\n" "{\n" " var[0] = 0.2f;\n" " var[0] = 0.2f;\n" // <-- is initialized twice "}"); ASSERT_EQUALS("test.cpp:4:style:Variable 'var[0]' is reassigned a value before the old one has been used.\n" "test.cpp:3:note:var[0] is assigned\n" "test.cpp:4:note:var[0] is overwritten\n", errout.str()); check("void f(float * var)\n" "{\n" " *var = 0.2f;\n" " *var = 0.2f;\n" // <-- is initialized twice "}"); ASSERT_EQUALS("test.cpp:4:style:Variable '*var' is reassigned a value before the old one has been used.\n" "test.cpp:3:note:*var is assigned\n" "test.cpp:4:note:*var is overwritten\n", errout.str()); // Volatile variables check("void f() {\n" " volatile char *reg = (volatile char *)0x12345;\n" " *reg = 12;\n" " *reg = 34;\n" "}"); ASSERT_EQUALS("test.cpp:2:style:C-style pointer casting\n", errout.str()); check("void f(std::map& m, int key, int value) {\n" // #6379 " m[key] = value;\n" " m[key] = value;\n" "}\n"); ASSERT_EQUALS("test.cpp:3:style:Variable 'm[key]' is reassigned a value before the old one has been used.\n" "test.cpp:2:note:m[key] is assigned\n" "test.cpp:3:note:m[key] is overwritten\n", errout.str()); } void redundantVarAssignment_trivial() { check("void f() {\n" " int a = 0;\n" " a = 4;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " int a;\n" " a = 0;\n" " a = 4;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " unsigned a;\n" " a = 0u;\n" " a = 2u;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " void* a;\n" " a = (void*)0;\n" " a = p;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " void* a;\n" " a = (void*)0U;\n" " a = p;\n" "}"); ASSERT_EQUALS("", errout.str()); } void redundantVarAssignment_struct() { check("struct foo {\n" " int a,b;\n" "};\n" "\n" "int main() {\n" " struct foo x;\n" " x.a = _mm_set1_ps(1.0);\n" " x.a = _mm_set1_ps(2.0);\n" "}"); ASSERT_EQUALS("[test.cpp:7] -> [test.cpp:8]: (style) Variable 'x.a' is reassigned a value before the old one has been used.\n", errout.str()); check("void f() {\n" " struct AB ab;\n" " ab.x = 23;\n" " ab.y = 41;\n" " ab.x = 1;\n" "}"); ASSERT_EQUALS("[test.cpp:3] -> [test.cpp:5]: (style) Variable 'ab.x' is reassigned a value before the old one has been used.\n", errout.str()); check("void f() {\n" " struct AB ab = {0};\n" " ab = foo();\n" "}"); ASSERT_EQUALS("", errout.str()); } void redundantVarAssignment_7133() { // #7133 check("sal_Int32 impl_Export() {\n" " try {\n" " try {\n" " uno::Sequence< uno::Any > aArgs(2);\n" " beans::NamedValue aValue;\n" " aValue.Name = \"DocumentHandler\";\n" " aValue.Value <<= xDocHandler;\n" " aArgs[0] <<= aValue;\n" " aValue.Name = \"Model\";\n" " aValue.Value <<= xDocumentComp;\n" " aArgs[1] <<= aValue;\n" " }\n" " catch (const uno::Exception&) {\n" " }\n" " }\n" " catch (const uno::Exception&) {\n" " }\n" "}", "test.cpp", true); ASSERT_EQUALS("", errout.str()); check("void ConvertBitmapData(sal_uInt16 nDestBits) {\n" " BitmapBuffer aSrcBuf;\n" " aSrcBuf.mnBitCount = nSrcBits;\n" " BitmapBuffer aDstBuf;\n" " aSrcBuf.mnBitCount = nDestBits;\n" " bConverted = ::ImplFastBitmapConversion( aDstBuf, aSrcBuf, aTwoRects );\n" "}", "test.c"); ASSERT_EQUALS("[test.c:3] -> [test.c:5]: (style) Variable 'aSrcBuf.mnBitCount' is reassigned a value before the old one has been used.\n", errout.str()); check("void ConvertBitmapData(sal_uInt16 nDestBits) {\n" " BitmapBuffer aSrcBuf;\n" " aSrcBuf.mnBitCount = nSrcBits;\n" " BitmapBuffer aDstBuf;\n" " aSrcBuf.mnBitCount = nDestBits;\n" " bConverted = ::ImplFastBitmapConversion( aDstBuf, aSrcBuf, aTwoRects );\n" "}"); ASSERT_EQUALS("[test.cpp:3] -> [test.cpp:5]: (style) Variable 'aSrcBuf.mnBitCount' is reassigned a value before the old one has been used.\n", errout.str()); check("class C { void operator=(int x); };\n" // #8368 - assignment operator might have side effects => inconclusive "void f() {\n" " C c;\n" " c = x;\n" " c = x;\n" "}"); ASSERT_EQUALS("[test.cpp:4] -> [test.cpp:5]: (style, inconclusive) Variable 'c' is reassigned a value before the old one has been used if variable is no semaphore variable.\n", errout.str()); } void redundantVarAssignment_stackoverflow() { check("typedef struct message_node {\n" " char code;\n" " size_t size;\n" " struct message_node *next, *prev;\n" "} *message_list;\n" "static message_list remove_message_from_list(message_list m) {\n" " m->prev->next = m->next;\n" " m->next->prev = m->prev;\n" " return m->next;\n" "}"); ASSERT_EQUALS("", errout.str()); } void redundantVarAssignment_lambda() { // #7152 check("int foo() {\n" " int x = 0, y = 0;\n" " auto f = [&]() { if (x < 5) ++y; };\n" " x = 2;\n" " f();\n" " x = 6;\n" " f();\n" " return y;\n" "}"); ASSERT_EQUALS("", errout.str()); // #10228 check("std::tuple g();\n" "void h(int);\n" "void f() {\n" " auto [a, b] = g();\n" " auto l = [a = a]() { h(i); };\n" "}\n"); ASSERT_EQUALS("", errout.str()); } void redundantVarAssignment_loop() { check("void f() {\n" " char buf[10];\n" " int i;\n" " for (i = 0; i < 4; i++)\n" " buf[i] = 131;\n" " buf[i] = 0;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void bar() {\n" // #9262 do-while with break " int x = 0;\n" " x = 432;\n" " do {\n" " if (foo()) break;\n" " x = 1;\n" " } while (false);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(int num) {\n" // #9420 FP " int a = num;\n" " for (int b = 0; b < num; a = b++)\n" " dostuff(a);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(int num) {\n" // #9420 FN " int a = num;\n" " for (int b = 0; b < num; a = b++);\n" "}"); TODO_ASSERT_EQUALS("error", "", errout.str()); } void redundantVarAssignment_after_switch() { check("void f(int x) {\n" // #7907 " int ret;\n" " switch (x) {\n" " case 123:\n" " ret = 1;\n" // redundant assignment " break;\n" " }\n" " ret = 3;\n" "}"); ASSERT_EQUALS("[test.cpp:5] -> [test.cpp:8]: (style) Variable 'ret' is reassigned a value before the old one has been used.\n", errout.str()); } void redundantVarAssignment_pointer() { check("void f(int *ptr) {\n" " int *x = ptr + 1;\n" " *x = 23;\n" " foo(ptr);\n" " *x = 32;\n" "}"); ASSERT_EQUALS("", errout.str()); // #8997 check("void f() {\n" " char x[2];\n" " char* p = x;\n" " *p = 1;\n" " p += 1;\n" " *p = 1;\n" "}"); ASSERT_EQUALS("", errout.str()); } void redundantVarAssignment_pointer_parameter() { check("void f(int *p) {\n" " *p = 1;\n" " if (condition) return;\n" " *p = 2;\n" "}"); ASSERT_EQUALS("", errout.str()); } void redundantVarAssignment_array() { check("void f() {\n" " int arr[10];\n" " int i = 0;\n" " arr[i] = 1;\n" " i += 2;\n" " arr[i] = 3;\n" " dostuff(arr);\n" "}"); ASSERT_EQUALS("", errout.str()); } void redundantVarAssignment_switch_break() { // #10058 check("void f(int a, int b) {\n" " int ret = 0;\n" " switch (a) {\n" " case 1:\n" " ret = 543;\n" " if (b) break;\n" " ret = 1;\n" " break;\n" " }" " return ret;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(int a, int b) {\n" " int ret = 0;\n" " switch (a) {\n" " case 1:\n" " ret = 543;\n" " if (b) break;\n" " ret = 1;\n" " break;\n" " }" "}"); ASSERT_EQUALS("[test.cpp:5] -> [test.cpp:7]: (style) Variable 'ret' is reassigned a value before the old one has been used.\n", errout.str()); } void redundantInitialization() { setMultiline(); check("void f() {\n" " int err = -ENOMEM;\n" " err = dostuff();\n" "}"); ASSERT_EQUALS("test.cpp:3:style:Redundant initialization for 'err'. The initialized value is overwritten before it is read.\n" "test.cpp:2:note:err is initialized\n" "test.cpp:3:note:err is overwritten\n", errout.str()); check("void f() {\n" " struct S s = {1,2,3};\n" " s = dostuff();\n" "}"); ASSERT_EQUALS("test.cpp:3:style:Redundant initialization for 's'. The initialized value is overwritten before it is read.\n" "test.cpp:2:note:s is initialized\n" "test.cpp:3:note:s is overwritten\n", errout.str()); check("void f() {\n" " int *p = NULL;\n" " p = dostuff();\n" "}"); ASSERT_EQUALS("", errout.str()); // "trivial" initialization => do not warn check("void f() {\n" " struct S s = {0};\n" " s = dostuff();\n" "}"); ASSERT_EQUALS("", errout.str()); check("namespace N { enum E {e0,e1}; }\n" "void f() {\n" " N::E e = N::e0;\n" // #9261 " e = dostuff();\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" // #10143 " std::shared_ptr i = g();\n" " h();\n" " i = nullptr;\n" "}\n"); ASSERT_EQUALS("", errout.str()); check("int f(const std::vector& v) {\n" // #9815 " int i = g();\n" " i = std::distance(v.begin(), std::find_if(v.begin(), v.end(), [=](int j) { return i == j; }));\n" " return i;\n" "}\n"); ASSERT_EQUALS("", errout.str()); } void redundantMemWrite() { return; // FIXME: temporary hack // Simple tests // cppcheck-suppress unreachableCode - remove when code is enabled again check("void f() {\n" " char a[10];\n" " memcpy(a, foo, bar);\n" " memset(a, 0, bar);\n" "}"); ASSERT_EQUALS("[test.cpp:3] -> [test.cpp:4]: (performance) Buffer 'a' is being written before its old content has been used.\n", errout.str()); check("void f() {\n" " char a[10];\n" " strcpy(a, foo);\n" " strncpy(a, 0, bar);\n" "}"); ASSERT_EQUALS("[test.cpp:3] -> [test.cpp:4]: (performance) Buffer 'a' is being written before its old content has been used.\n", errout.str()); check("void f() {\n" " char a[10];\n" " sprintf(a, \"foo\");\n" " memmove(a, 0, bar);\n" "}"); ASSERT_EQUALS("[test.cpp:3] -> [test.cpp:4]: (performance) Buffer 'a' is being written before its old content has been used.\n", errout.str()); check("void f(char *filename) {\n" " char *p = strrchr(filename,'.');\n" " strcpy(p, \"foo\");\n" " dostuff(filename);\n" " strcpy(p, \"foo\");\n" "}"); ASSERT_EQUALS("", errout.str()); // Writing to different parts of a buffer check("void f(void* a) {\n" " memcpy(a, foo, bar);\n" " memset(a+5, 0, bar);\n" "}"); ASSERT_EQUALS("", errout.str()); // Use variable as second argument check("void f(void* a, void* b) {\n" " memset(a, 0, 5);\n" " memcpy(b, a, 5);\n" " memset(a, 1, 5);\n" "}"); ASSERT_EQUALS("", errout.str()); // strcat is special check("void f() {\n" " char a[10];\n" " strcpy(a, foo);\n" " strcat(a, bar);\n" // Not redundant " strcpy(a, x);\n" // Redundant "}"); ASSERT_EQUALS("[test.cpp:3] -> [test.cpp:5]: (performance) Buffer 'a' is being written before its old content has been used.\n", errout.str()); // Tests with function call between copy check("void f() {\n" " char a[10];\n" " snprintf(a, foo, bar);\n" " bar();\n" " memset(a, 0, size);\n" "}"); ASSERT_EQUALS("[test.cpp:3] -> [test.cpp:5]: (performance) Buffer 'a' is being written before its old content has been used.\n", errout.str()); check("void* a;\n" "void f() {\n" " memset(a, 0, size);\n" " bar();\n" // Global variable might be accessed in bar() " memset(a, 0, size);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " char a[10];\n" " memset(a, 0, size);\n" " bar();\n" " memset(a, 0, size);\n" "}"); TODO_ASSERT_EQUALS("[test.cpp:3] -> [test.cpp:5]: (performance) Buffer 'a' is being written before its old content has been used.\n", "", errout.str()); check("void bar(void* a) {}\n" "void f(void* a) {\n" " memset(a, 0, size);\n" " bar(a);\n" // Passed as argument " memset(a, 0, size);\n" "}"); ASSERT_EQUALS("", errout.str()); // Branch tests check("void f(void* a) {\n" " memset(a, 0, size);\n" " if(x)\n" " memset(a, 0, size);\n" "}"); ASSERT_EQUALS("", errout.str()); // #4455 - initialization of local buffer check("void f(void) {" " char buf[10];\n" " memset(buf, 0, 10);\n" " strcpy(buf, string);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(void) {\n" " char buf[10] = {0};\n" " memset(buf, 0, 10);\n" " strcpy(buf, string);\n" "}"); ASSERT_EQUALS("[test.cpp:3] -> [test.cpp:4]: (performance) Buffer 'buf' is being written before its old content has been used.\n", errout.str()); // #5689 - use return value of strcpy check("int f(void* a) {\n" " int i = atoi(strcpy(a, foo));\n" " strncpy(a, 0, bar);\n" " return i;\n" "}"); ASSERT_EQUALS("", errout.str()); // #7175 - read+write check("void f() {\n" " char buf[100];\n" " strcpy(buf, x);\n" " strcpy(buf, dostuff(buf));\n" // <- read + write " strcpy(buf, x);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " char buf[100];\n" " strcpy(buf, x);\n" " strcpy(buf, dostuff(buf));\n" " strcpy(buf, x);\n" "}"); TODO_ASSERT_EQUALS("error", "", errout.str()); } void varFuncNullUB() { // #4482 check("void a(...);\n" "void b() { a(NULL); }"); ASSERT_EQUALS("[test.cpp:2]: (portability) Passing NULL after the last typed argument to a variadic function leads to undefined behaviour.\n", errout.str()); check("void a(char *p, ...);\n" "void b() { a(NULL, 2); }"); ASSERT_EQUALS("", errout.str()); } void checkCastIntToCharAndBack() { // #160 // check getchar check("void f() {\n" "unsigned char c; c = getchar();\n" " while( c != EOF)\n" " {\n" " bar(c);\n" " c = getchar();\n" " } ;\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (warning) Storing getchar() return value in char variable and then comparing with EOF.\n", errout.str()); check("void f() {\n" "unsigned char c = getchar();\n" " while( EOF != c)\n" " {\n" " bar(c);\n" " } ;\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (warning) Storing getchar() return value in char variable and then comparing with EOF.\n", errout.str()); check("void f() {\n" " unsigned char c; c = getchar();\n" " while( EOF != c )\n" " {\n" " bar(c);\n" " c = getchar();\n" " } ;\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (warning) Storing getchar() return value in char variable and then comparing with EOF.\n", errout.str()); check("void f() {\n" " unsigned char c;\n" " while( EOF != ( c = getchar() ) )\n" " {\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (warning) Storing getchar() return value in char variable and then comparing with EOF.\n", errout.str()); check("void f() {\n" " int i; i = getchar();\n" " while( i != EOF)\n" " {\n" " bar(i);\n" " i = getchar();\n" " } ;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " int i; i = getchar();\n" " while( EOF != i )\n" " {\n" " bar(i);\n" " i = getchar();\n" " } ;\n" "}"); ASSERT_EQUALS("", errout.str()); // check getc check("void f (FILE * pFile){\n" "unsigned char c;\n" "do {\n" " c = getc (pFile);\n" "} while (c != EOF)" "}"); ASSERT_EQUALS("[test.cpp:5]: (warning) Storing getc() return value in char variable and then comparing with EOF.\n", errout.str()); check("void f (FILE * pFile){\n" "unsigned char c;\n" "do {\n" " c = getc (pFile);\n" "} while (EOF != c)" "}"); ASSERT_EQUALS("[test.cpp:5]: (warning) Storing getc() return value in char variable and then comparing with EOF.\n", errout.str()); check("void f (FILE * pFile){\n" "int i;\n" "do {\n" " i = getc (pFile);\n" "} while (i != EOF)" "}"); ASSERT_EQUALS("", errout.str()); check("void f (FILE * pFile){\n" "int i;\n" "do {\n" " i = getc (pFile);\n" "} while (EOF != i)" "}"); ASSERT_EQUALS("", errout.str()); // check fgetc check("void f (FILE * pFile){\n" "unsigned char c;\n" "do {\n" " c = fgetc (pFile);\n" "} while (c != EOF)" "}"); ASSERT_EQUALS("[test.cpp:5]: (warning) Storing fgetc() return value in char variable and then comparing with EOF.\n", errout.str()); check("void f (FILE * pFile){\n" "char c;\n" "do {\n" " c = fgetc (pFile);\n" "} while (EOF != c)" "}"); ASSERT_EQUALS("[test.cpp:5]: (warning) Storing fgetc() return value in char variable and then comparing with EOF.\n", errout.str()); check("void f (FILE * pFile){\n" "signed char c;\n" "do {\n" " c = fgetc (pFile);\n" "} while (EOF != c)" "}"); ASSERT_EQUALS("", errout.str()); check("void f (FILE * pFile){\n" "int i;\n" "do {\n" " i = fgetc (pFile);\n" "} while (i != EOF)" "}"); ASSERT_EQUALS("", errout.str()); check("void f (FILE * pFile){\n" "int i;\n" "do {\n" " i = fgetc (pFile);\n" "} while (EOF != i)" "}"); ASSERT_EQUALS("", errout.str()); // cin.get() check("void f(){\n" " char ch; ch = std::cin.get();\n" " while (EOF != ch) {\n" " std::cout << ch;\n" " ch = std::cin.get();\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (warning) Storing cin.get() return value in char variable and then comparing with EOF.\n", errout.str()); check("void f(){\n" " char ch; ch = std::cin.get();\n" " while (ch != EOF) {\n" " std::cout << ch;\n" " ch = std::cin.get();\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (warning) Storing cin.get() return value in char variable and then comparing with EOF.\n", errout.str()); check("void f(){\n" " int i; i = std::cin.get();\n" " while ( EOF != i ) {\n" " std::cout << i;\n" " i = std::cin.get();\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(){\n" " int i; i = std::cin.get();\n" " while ( i != EOF ) {\n" " std::cout << i;\n" " i = std::cin.get();\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); } void checkCommaSeparatedReturn() { check("int fun(int a) {\n" " if (a < 0)\n" " return a++,\n" " do_something();\n" "}", nullptr, false, false); TODO_ASSERT_EQUALS("[test.cpp:3]: (style) Comma is used in return statement. The comma can easily be misread as a ';'.\n", "", errout.str()); check("int fun(int a) {\n" " if (a < 0)\n" " return a++, do_something();\n" "}", nullptr, false, false); ASSERT_EQUALS("", errout.str()); check("int fun(int a) {\n" " if (a < 0)\n" " return a+5,\n" " do_something();\n" "}", nullptr, false, false); TODO_ASSERT_EQUALS("[test.cpp:3]: (style) Comma is used in return statement. The comma can easily be misread as a ';'.\n", "", errout.str()); check("int fun(int a) {\n" " if (a < 0)\n" " return a+5, do_something();\n" "}", nullptr, false, false); ASSERT_EQUALS("", errout.str()); check("int fun(int a) {\n" " if (a < 0)\n" " return c::b;\n" "}", nullptr, false, false); ASSERT_EQUALS("", errout.str()); // #4943 take care of C++11 initializer lists check("std::vector Bar() {\n" " return\n" " {\n" " { \"1\" },\n" " { \"2\" },\n" " { \"3\" }\n" " };\n" "}", nullptr, false, false); ASSERT_EQUALS("", errout.str()); } void checkPassByReference() { // #8570 passByValue when std::move is used check("struct A\n" "{\n" " std::vector x;\n" "};\n" "\n" "struct B\n" "{\n" " explicit B(A a) : a(std::move(a)) {}\n" " void Init(A _a) { a = std::move(_a); }\n" " A a;" "};", nullptr, false, true); ASSERT_EQUALS("", errout.str()); check("struct A\n" "{\n" " std::vector x;\n" "};\n" "\n" "struct B\n" "{\n" " explicit B(A a) : a{std::move(a)} {}\n" " void Init(A _a) { a = std::move(_a); }\n" " A a;" "};", nullptr, false, true); ASSERT_EQUALS("", errout.str()); check("struct A\n" "{\n" " std::vector x;\n" "};\n" "\n" "struct B\n" "{\n" " B(A a, A a2) : a{std::move(a)}, a2{std::move(a2)} {}\n" " void Init(A _a) { a = std::move(_a); }\n" " A a;" " A a2;" "};", nullptr, false, true); ASSERT_EQUALS("", errout.str()); check("struct A\n" "{\n" " std::vector x;\n" "};\n" "\n" "struct B\n" "{\n" " B(A a, A a2) : a{std::move(a)}, a2{a2} {}\n" " void Init(A _a) { a = std::move(_a); }\n" " A a;" " A a2;" "};", nullptr, false, true); ASSERT_EQUALS("[test.cpp:8]: (performance) Function parameter 'a2' should be passed by const reference.\n", errout.str()); check("struct A\n" "{\n" " std::vector x;\n" "};\n" "\n" "struct B\n" "{\n" " B(A a, A a2) : a{std::move(a)}, a2(a2) {}\n" " void Init(A _a) { a = std::move(_a); }\n" " A a;" " A a2;" "};", nullptr, false, true); ASSERT_EQUALS("[test.cpp:8]: (performance) Function parameter 'a2' should be passed by const reference.\n", errout.str()); check("std::map m;\n" // #10817 "void f(const decltype(m)::const_iterator i) {}"); ASSERT_EQUALS("", errout.str()); } void checkComparisonFunctionIsAlwaysTrueOrFalse() { // positive test check("bool f(int x){\n" " return isless(x,x);\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (warning) Comparison of two identical variables with isless(x,x) always evaluates to false.\n", errout.str()); check("bool f(int x){\n" " return isgreater(x,x);\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (warning) Comparison of two identical variables with isgreater(x,x) always evaluates to false.\n", errout.str()); check("bool f(int x){\n" " return islessgreater(x,x);\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (warning) Comparison of two identical variables with islessgreater(x,x) always evaluates to false.\n", errout.str()); check("bool f(int x){\n" " return islessequal(x,x);\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (warning) Comparison of two identical variables with islessequal(x,x) always evaluates to true.\n", errout.str()); check("bool f(int x){\n" " return isgreaterequal(x,x);\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (warning) Comparison of two identical variables with isgreaterequal(x,x) always evaluates to true.\n", errout.str()); // no warning should be reported for check("bool f(int x, int y){\n" " return isgreaterequal(x,y) && islessequal(x,y) && islessgreater(x,y) && isgreater(x,y) && isless(x,y);\n" "}"); ASSERT_EQUALS("", errout.str()); } void integerOverflow() { // 5895 // no signed integer overflow should happen check("void f(unsigned long long ull) {\n" " if (ull == 0x89504e470d0a1a0a || ull == 0x8a4d4e470d0a1a0a) ;\n" "}"); ASSERT_EQUALS("", errout.str()); } void redundantPointerOp() { check("int *f(int *x) {\n" " return &*x;\n" "}\n", nullptr, true); ASSERT_EQUALS("[test.cpp:2]: (style) Redundant pointer operation on 'x' - it's already a pointer.\n", errout.str()); check("int *f(int *y) {\n" " return &(*y);\n" "}\n", nullptr, true); ASSERT_EQUALS("[test.cpp:2]: (style) Redundant pointer operation on 'y' - it's already a pointer.\n", errout.str()); check("int f() {\n" // #10991 " int value = 4;\n" " int result1 = *(&value);\n" " int result2 = *&value;\n" " return result1 + result2;\n" "}\n", nullptr, true); ASSERT_EQUALS("[test.cpp:3]: (style) Redundant pointer operation on 'value' - it's already a variable.\n" "[test.cpp:4]: (style) Redundant pointer operation on 'value' - it's already a variable.\n", errout.str()); check("void f(int& a, int b) {\n" " *(&a) = b;\n" "}\n", nullptr, true); ASSERT_EQUALS("[test.cpp:2]: (style) Redundant pointer operation on 'a' - it's already a variable.\n", errout.str()); check("void f(int**& p) {}\n", nullptr, true); ASSERT_EQUALS("", errout.str()); checkP("#define RESTORE(ORIG, COPY) { *ORIG = *COPY; }\n" "void f(int* p, int i) {\n" " RESTORE(p, &i);\n" "}\n"); ASSERT_EQUALS("", errout.str()); // no warning for bitwise AND check("void f(const int *b) {\n" " int x = 0x20 & *b;\n" "}\n", nullptr, true); ASSERT_EQUALS("", errout.str()); // No message for double pointers to structs check("void f(struct foo **my_struct) {\n" " char **pass_to_func = &(*my_struct)->buf;\n" "}\n", nullptr, true); ASSERT_EQUALS("", errout.str()); // another double pointer to struct - with an array check("void f(struct foo **my_struct) {\n" " char **pass_to_func = &(*my_struct)->buf[10];\n" "}\n", nullptr, true); ASSERT_EQUALS("", errout.str()); // double pointer to array check("void f(char **ptr) {\n" " int *x = &(*ptr)[10];\n" "}\n", nullptr, true); ASSERT_EQUALS("[test.cpp:2]: (style) Variable 'x' can be declared as pointer to const\n", errout.str()); // function calls check("void f(Mutex *mut) {\n" " pthread_mutex_lock(&*mut);\n" "}\n", nullptr, false); ASSERT_EQUALS("[test.cpp:2]: (style) Redundant pointer operation on 'mut' - it's already a pointer.\n", errout.str()); // make sure we got the AST match for "(" right check("void f(char *ptr) {\n" " if (&*ptr == NULL)\n" " return;\n" "}\n", nullptr, true); ASSERT_EQUALS("[test.cpp:2]: (style) Redundant pointer operation on 'ptr' - it's already a pointer.\n", errout.str()); // no warning for macros checkP("#define MUTEX_LOCK(m) pthread_mutex_lock(&(m))\n" "void f(struct mutex *mut) {\n" " MUTEX_LOCK(*mut);\n" "}\n"); ASSERT_EQUALS("", errout.str()); checkP("#define B(op) bar(op)\n" "#define C(orf) B(&orf)\n" "void foo(const int * pkey) {\n" " C(*pkey);\n" "}\n"); ASSERT_EQUALS("", errout.str()); } void test_isSameExpression() { // see #5738 check("bool isInUnoIncludeFile(StringRef name) {" " return name.startswith(SRCDIR \"/com/\") || name.startswith(SRCDIR \"/uno/\");\n" "};", "test.cpp", false); ASSERT_EQUALS("", errout.str()); } void raceAfterInterlockedDecrement() { checkInterlockedDecrement("void f() {\n" " int counter = 0;\n" " InterlockedDecrement(&counter);\n" " whatever();\n" "}"); ASSERT_EQUALS("", errout.str()); checkInterlockedDecrement("void f() {\n" " int counter = 0;\n" " InterlockedDecrement(&counter);\n" " if (counter)\n" " return;\n" " destroy();\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (error) Race condition: non-interlocked access after InterlockedDecrement(). Use InterlockedDecrement() return value instead.\n", errout.str()); checkInterlockedDecrement("void f() {\n" " int counter = 0;\n" " InterlockedDecrement(&counter);\n" " if (!counter)\n" " destroy();\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (error) Race condition: non-interlocked access after InterlockedDecrement(). Use InterlockedDecrement() return value instead.\n", errout.str()); checkInterlockedDecrement("void f() {\n" " int counter = 0;\n" " InterlockedDecrement(&counter);\n" " if (counter > 0)\n" " return;\n" " destroy();\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (error) Race condition: non-interlocked access after InterlockedDecrement(). Use InterlockedDecrement() return value instead.\n", errout.str()); checkInterlockedDecrement("void f() {\n" " int counter = 0;\n" " InterlockedDecrement(&counter);\n" " if (0 < counter)\n" " return;\n" " destroy();\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (error) Race condition: non-interlocked access after InterlockedDecrement(). Use InterlockedDecrement() return value instead.\n", errout.str()); checkInterlockedDecrement("void f() {\n" " int counter = 0;\n" " InterlockedDecrement(&counter);\n" " if (counter == 0)\n" " destroy();\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (error) Race condition: non-interlocked access after InterlockedDecrement(). Use InterlockedDecrement() return value instead.\n", errout.str()); checkInterlockedDecrement("void f() {\n" " int counter = 0;\n" " InterlockedDecrement(&counter);\n" " if (0 == counter)\n" " destroy();\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (error) Race condition: non-interlocked access after InterlockedDecrement(). Use InterlockedDecrement() return value instead.\n", errout.str()); checkInterlockedDecrement("void f() {\n" " int counter = 0;\n" " InterlockedDecrement(&counter);\n" " if (0 != counter)\n" " return;\n" " destroy()\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (error) Race condition: non-interlocked access after InterlockedDecrement(). Use InterlockedDecrement() return value instead.\n", errout.str()); checkInterlockedDecrement("void f() {\n" " int counter = 0;\n" " InterlockedDecrement(&counter);\n" " if (counter != 0)\n" " return;\n" " destroy()\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (error) Race condition: non-interlocked access after InterlockedDecrement(). Use InterlockedDecrement() return value instead.\n", errout.str()); checkInterlockedDecrement("void f() {\n" " int counter = 0;\n" " InterlockedDecrement(&counter);\n" " if (counter <= 0)\n" " destroy();\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (error) Race condition: non-interlocked access after InterlockedDecrement(). Use InterlockedDecrement() return value instead.\n", errout.str()); checkInterlockedDecrement("void f() {\n" " int counter = 0;\n" " InterlockedDecrement(&counter);\n" " if (0 >= counter)\n" " destroy();\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (error) Race condition: non-interlocked access after InterlockedDecrement(). Use InterlockedDecrement() return value instead.\n", errout.str()); checkInterlockedDecrement("void f() {\n" " int counter = 0;\n" " int newCount = InterlockedDecrement(&counter);\n" " if (newCount)\n" " return;\n" " destroy();\n" "}"); ASSERT_EQUALS("", errout.str()); checkInterlockedDecrement("void f() {\n" " int counter = 0;\n" " int newCount = InterlockedDecrement(&counter);\n" " if (!newCount)\n" " destroy();\n" "}"); ASSERT_EQUALS("", errout.str()); checkInterlockedDecrement("void f() {\n" " int counter = 0;\n" " int newCount = InterlockedDecrement(&counter);\n" " if (newCount > 0)\n" " return;\n" " destroy();\n" "}"); ASSERT_EQUALS("", errout.str()); checkInterlockedDecrement("void f() {\n" " int counter = 0;\n" " int newCount = InterlockedDecrement(&counter);\n" " if (0 < newCount)\n" " return;\n" " destroy();\n" "}"); ASSERT_EQUALS("", errout.str()); checkInterlockedDecrement("void f() {\n" " int counter = 0;\n" " int newCount = InterlockedDecrement(&counter);\n" " if (newCount == 0)\n" " destroy();\n" "}"); ASSERT_EQUALS("", errout.str()); checkInterlockedDecrement("void f() {\n" " int counter = 0;\n" " int newCount = InterlockedDecrement(&counter);\n" " if (0 == newCount)\n" " destroy();\n" "}"); ASSERT_EQUALS("", errout.str()); checkInterlockedDecrement("void f() {\n" " int counter = 0;\n" " int newCount = InterlockedDecrement(&counter);\n" " if (0 != newCount)\n" " return;\n" " destroy()\n" "}"); ASSERT_EQUALS("", errout.str()); checkInterlockedDecrement("void f() {\n" " int counter = 0;\n" " int newCount = InterlockedDecrement(&counter);\n" " if (newCount != 0)\n" " return;\n" " destroy()\n" "}"); ASSERT_EQUALS("", errout.str()); checkInterlockedDecrement("void f() {\n" " int counter = 0;\n" " int newCount = InterlockedDecrement(&counter);\n" " if (newCount <= 0)\n" " destroy();\n" "}"); ASSERT_EQUALS("", errout.str()); checkInterlockedDecrement("void f() {\n" " int counter = 0;\n" " int newCount = InterlockedDecrement(&counter);\n" " if (0 >= newCount)\n" " destroy;\n" "}"); ASSERT_EQUALS("", errout.str()); checkInterlockedDecrement("int f() {\n" " int counter = 0;\n" " if (InterlockedDecrement(&counter) == 0) {\n" " destroy();\n" " return 0;\n" " } else {\n" " return counter;\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:7]: (error) Race condition: non-interlocked access after InterlockedDecrement(). Use InterlockedDecrement() return value instead.\n", errout.str()); checkInterlockedDecrement("int f() {\n" " int counter = 0;\n" " if (::InterlockedDecrement(&counter) == 0) {\n" " destroy();\n" " return 0;\n" " } else {\n" " return counter;\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:7]: (error) Race condition: non-interlocked access after InterlockedDecrement(). Use InterlockedDecrement() return value instead.\n", errout.str()); checkInterlockedDecrement("int f() {\n" " int counter = 0;\n" " if (InterlockedDecrement(&counter) == 0) {\n" " destroy();\n" " return 0;\n" " }\n" " return counter;\n" "}"); ASSERT_EQUALS("[test.cpp:7]: (error) Race condition: non-interlocked access after InterlockedDecrement(). Use InterlockedDecrement() return value instead.\n", errout.str()); checkInterlockedDecrement("int f() {\n" " int counter = 0;\n" " if (::InterlockedDecrement(&counter) == 0) {\n" " destroy();\n" " return 0;\n" " }\n" " return counter;\n" "}"); ASSERT_EQUALS("[test.cpp:7]: (error) Race condition: non-interlocked access after InterlockedDecrement(). Use InterlockedDecrement() return value instead.\n", errout.str()); checkInterlockedDecrement("int f() {\n" " int counter = 0;\n" " if (InterlockedDecrement(&counter) == 0) {\n" " destroy();\n" " return 0;\n" " } else\n" " return counter;\n" " \n" "}"); ASSERT_EQUALS("[test.cpp:7]: (error) Race condition: non-interlocked access after InterlockedDecrement(). Use InterlockedDecrement() return value instead.\n", errout.str()); checkInterlockedDecrement("int f() {\n" " int counter = 0;\n" " if (::InterlockedDecrement(&counter) == 0) {\n" " destroy();\n" " return 0;\n" " } else\n" " return counter;\n" " \n" "}"); ASSERT_EQUALS("[test.cpp:7]: (error) Race condition: non-interlocked access after InterlockedDecrement(). Use InterlockedDecrement() return value instead.\n", errout.str()); } void testUnusedLabel() { check("void f() {\n" " label:\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Label 'label' is not used.\n", errout.str()); check("void f() {\n" " label:\n" " foo();\n" " goto label;\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " label:\n" " foo();\n" " goto label;\n" "}\n" "void g() {\n" " label:\n" "}"); ASSERT_EQUALS("[test.cpp:7]: (style) Label 'label' is not used.\n", errout.str()); check("void f() {\n" " switch(a) {\n" " default:\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " class X {\n" " protected:\n" " };\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " class X {\n" " my_protected:\n" " };\n" "}"); ASSERT_EQUALS("", errout.str()); check("int test(char art) {\n" " switch (art) {\n" " caseZERO:\n" " return 0;\n" " case1:\n" " return 1;\n" " case 2:\n" " return 2;\n" " }\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (warning) Label 'caseZERO' is not used. Should this be a 'case' of the enclosing switch()?\n" "[test.cpp:5]: (warning) Label 'case1' is not used. Should this be a 'case' of the enclosing switch()?\n", errout.str()); check("int test(char art) {\n" " switch (art) {\n" " case 2:\n" " return 2;\n" " }\n" " label:\n" "}"); ASSERT_EQUALS("[test.cpp:6]: (style) Label 'label' is not used.\n", errout.str()); } void testEvaluationOrder() { check("void f() {\n" " int x = dostuff();\n" " return x + x++;\n" "}", "test.c"); ASSERT_EQUALS("[test.c:3]: (error) Expression 'x+x++' depends on order of evaluation of side effects\n", errout.str()); // #7226 check("long int f1(const char *exp) {\n" " return strtol(++exp, (char **)&exp, 10);\n" "}", "test.c"); ASSERT_EQUALS("", errout.str()); check("long int f1(const char *exp) {\n" " return dostuff(++exp, exp, 10);\n" "}", "test.c"); ASSERT_EQUALS("[test.c:2]: (error) Expression '++exp,exp' depends on order of evaluation of side effects\n", errout.str()); check("void f() {\n" " int a;\n" " while (a=x(), a==123) {}\n" "}", "test.c"); ASSERT_EQUALS("", errout.str()); // # 8717 check("void f(int argc, char *const argv[]) {\n" " char **local_argv = safe_malloc(sizeof (*local_argv));\n" " int local_argc = 0;\n" " local_argv[local_argc++] = argv[0];\n" "}\n", "test.c"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " int x = 0;\n" " return 0 + x++;\n" "}\n", "test.c"); ASSERT_EQUALS("", errout.str()); check("void f(int x, int y) {\n" " int a[10];\n" " a[x+y] = a[y+x]++;;\n" "}\n", "test.c"); ASSERT_EQUALS("[test.c:3]: (error) Expression 'a[x+y]=a[y+x]++' depends on order of evaluation of side effects\n", errout.str()); } void testEvaluationOrderSelfAssignment() { // self assignment check("void f() {\n" " int x = x = y + 1;\n" "}", "test.c"); ASSERT_EQUALS("[test.c:2]: (warning) Redundant assignment of 'x' to itself.\n", errout.str()); } void testEvaluationOrderMacro() { // macro, don't bailout (#7233) checkP("#define X x\n" "void f(int x) {\n" " return x + X++;\n" "}", "test.c"); ASSERT_EQUALS("[test.c:3]: (error) Expression 'x+x++' depends on order of evaluation of side effects\n", errout.str()); } void testEvaluationOrderSequencePointsFunctionCall() { // FP check("void f(int id) {\n" " id = dostuff(id += 42);\n" "}", "test.c"); ASSERT_EQUALS("", errout.str()); // FN check("void f(int id) {\n" " id = id + dostuff(id += 42);\n" "}", "test.c"); TODO_ASSERT_EQUALS("error", "", errout.str()); } void testEvaluationOrderSequencePointsComma() { check("int f(void) {\n" " int t;\n" " return (unsigned char)(t=1,t^c);\n" "}", "test.c"); ASSERT_EQUALS("", errout.str()); check("void f(void) {\n" " int t;\n" " dostuff(t=1,t^c);\n" "}", "test.c"); ASSERT_EQUALS("[test.c:3]: (error) Expression 't=1,t^c' depends on order of evaluation of side effects\n", errout.str()); check("void f(void) {\n" " int t;\n" " dostuff((t=1,t),2);\n" "}", "test.c"); ASSERT_EQUALS("", errout.str()); // #8230 check("void hprf(const char* fp) {\n" " do\n" " ;\n" " while (++fp, (*fp) <= 0177);\n" "}\n", "test.c"); ASSERT_EQUALS("", errout.str()); check("void hprf(const char* fp) {\n" " do\n" " ;\n" " while (i++, ++fp, (*fp) <= 0177);\n" "}\n", "test.c"); ASSERT_EQUALS("", errout.str()); check("void f(const char* fp) {\n" " do\n" " ;\n" " while (f(++fp, (*fp) <= 7));\n" "}\n", "test.c"); ASSERT_EQUALS("[test.c:4]: (error) Expression '++fp,(*fp)<=7' depends on order of evaluation of side effects\n", errout.str()); } void testEvaluationOrderSizeof() { check("void f(char *buf) {\n" " dostuff(buf++, sizeof(*buf));" "}", "test.c"); ASSERT_EQUALS("", errout.str()); } void testUnsignedLessThanZero() { check("struct d {\n" " unsigned n;\n" "};\n" "void f(void) {\n" " struct d d;\n" " d.n = 3;\n" "\n" " if (d.n < 0) {\n" " return;\n" " }\n" "\n" " if (0 > d.n) {\n" " return;\n" " }\n" "}", "test.c"); ASSERT_EQUALS("[test.c:8]: (style) Checking if unsigned expression 'd.n' is less than zero.\n" "[test.c:12]: (style) Checking if unsigned expression 'd.n' is less than zero.\n", errout.str()); } void doubleMove1() { check("void g(A a);\n" "void f() {\n" " A a;\n" " g(std::move(a));\n" " g(std::move(a));\n" "}"); ASSERT_EQUALS("[test.cpp:5]: (warning) Access of moved variable 'a'.\n", errout.str()); } void doubleMoveMemberInitialization1() { check("class A\n" "{\n" " A(B && b)\n" " :b1(std::move(b))\n" " {\n" " b2 = std::move(b);\n" " }\n" " B b1;\n" " B b2;\n" "};"); ASSERT_EQUALS("[test.cpp:6]: (warning) Access of moved variable 'b'.\n", errout.str()); } void doubleMoveMemberInitialization2() { check("class A\n" "{\n" " A(B && b)\n" " :b1(std::move(b)),\n" " b2(std::move(b))\n" " {}\n" " B b1;\n" " B b2;\n" "};"); ASSERT_EQUALS("[test.cpp:5]: (warning) Access of moved variable 'b'.\n", errout.str()); } void doubleMoveMemberInitialization3() { // #9974 check("struct A { int i; };\n" "struct B { A a1; A a2; };\n" "B f() {\n" " A a1 = { 1 };\n" " A a2 = { 2 };\n" " return { .a1 = std::move(a1), .a2 = std::move(a2) };\n" "}\n"); ASSERT_EQUALS("", errout.str()); } void moveAndAssign1() { check("A g(A a);\n" "void f() {\n" " A a;\n" " a = g(std::move(a));\n" " a = g(std::move(a));\n" "}"); ASSERT_EQUALS("", errout.str()); } void moveAndAssign2() { check("A g(A a);\n" "void f() {\n" " A a;\n" " B b = g(std::move(a));\n" " C c = g(std::move(a));\n" "}"); ASSERT_EQUALS("[test.cpp:5]: (warning) Access of moved variable 'a'.\n", errout.str()); } void moveAssignMoveAssign() { check("void h(A a);\n" "void f() {" " A a;\n" " g(std::move(a));\n" " h(a);\n" " a = b;\n" " h(a);\n" " g(std::move(a));\n" " h(a);\n" " a = b;\n" " h(a);\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (warning) Access of moved variable 'a'.\n" "[test.cpp:8]: (warning) Access of moved variable 'a'.\n", errout.str()); } void moveAndReset1() { check("A g(A a);\n" "void f() {\n" " A a;\n" " a.reset(g(std::move(a)));\n" " a.reset(g(std::move(a)));\n" "}"); ASSERT_EQUALS("", errout.str()); } void moveAndReset2() { check("A g(A a);\n" "void f() {\n" " A a;\n" " A b;\n" " A c;\n" " b.reset(g(std::move(a)));\n" " c.reset(g(std::move(a)));\n" "}"); ASSERT_EQUALS("[test.cpp:7]: (warning) Access of moved variable 'a'.\n", errout.str()); } void moveResetMoveReset() { check("void h(A a);\n" "void f() {" " A a;\n" " g(std::move(a));\n" " h(a);\n" " a.reset(b);\n" " h(a);\n" " g(std::move(a));\n" " h(a);\n" " a.reset(b);\n" " h(a);\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (warning) Access of moved variable 'a'.\n" "[test.cpp:8]: (warning) Access of moved variable 'a'.\n", errout.str()); } void moveAndFunctionParameter() { check("void g(A a);\n" "void f() {\n" " A a;\n" " A b = std::move(a);\n" " g(a);\n" " A c = a;\n" "}"); ASSERT_EQUALS("[test.cpp:5]: (warning) Access of moved variable 'a'.\n" "[test.cpp:6]: (warning) Access of moved variable 'a'.\n", errout.str()); } void moveAndFunctionParameterReference() { check("void g(A & a);\n" "void f() {\n" " A a;\n" " A b = std::move(a);\n" " g(a);\n" " A c = a;\n" "}"); ASSERT_EQUALS("", errout.str()); } void moveAndFunctionParameterConstReference() { check("void g(A const & a);\n" "void f() {\n" " A a;\n" " A b = std::move(a);\n" " g(a);\n" " A c = a;\n" "}"); ASSERT_EQUALS("[test.cpp:5]: (warning) Access of moved variable 'a'.\n" "[test.cpp:6]: (warning) Access of moved variable 'a'.\n", errout.str()); } void moveAndFunctionParameterUnknown() { check("void f() {\n" " A a;\n" " A b = std::move(a);\n" " g(a);\n" " A c = a;\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (warning, inconclusive) Access of moved variable 'a'.\n" "[test.cpp:5]: (warning, inconclusive) Access of moved variable 'a'.\n", errout.str()); } void moveAndReturn() { check("int f(int i) {\n" " A a;\n" " A b;\n" " g(std::move(a));\n" " if (i)\n" " return g(std::move(b));\n" " return h(std::move(a),std::move(b));\n" "}"); ASSERT_EQUALS("[test.cpp:7]: (warning) Access of moved variable 'a'.\n", errout.str()); } void moveAndClear() { check("void f() {\n" " V v;\n" " g(std::move(v));\n" " v.clear();\n" " if (v.empty()) {}\n" "}"); ASSERT_EQUALS("", errout.str()); } void movedPointer() { check("void f() {\n" " P p;\n" " g(std::move(p));\n" " x = p->x;\n" " y = p->y;\n" "}"); ASSERT_EQUALS("[test.cpp:4]: (warning) Access of moved variable 'p'.\n" "[test.cpp:5]: (warning) Access of moved variable 'p'.\n", errout.str()); } void moveAndAddressOf() { check("void f() {\n" " std::string s1 = x;\n" " std::string s2 = std::move(s1);\n" " p = &s1;\n" "}"); ASSERT_EQUALS("", errout.str()); } void partiallyMoved() { check("void f() {\n" " A a;\n" " gx(std::move(a).x());\n" " gy(std::move(a).y());\n" "}"); ASSERT_EQUALS("", errout.str()); } void moveAndLambda() { check("void f() {\n" " A a;\n" " auto h = [a=std::move(a)](){return g(std::move(a));};" " b = a;\n" "}"); ASSERT_EQUALS("", errout.str()); } void moveInLoop() { check("void g(std::string&& s);\n" "void f() {\n" " std::string p;\n" " while(true)\n" " g(std::move(p));\n" "}\n"); ASSERT_EQUALS("[test.cpp:5]: (warning) Access of moved variable 'p'.\n", errout.str()); check("std::list g(std::list&&);\n" "void f(std::listl) {\n" " for(int i = 0; i < 10; ++i) {\n" " for (auto &j : g(std::move(l))) { (void)j; }\n" " }\n" "}\n"); ASSERT_EQUALS("[test.cpp:4]: (warning) Access of moved variable 'l'.\n", errout.str()); } void moveCallback() { check("bool f(std::function&& callback);\n" "void func(std::function callback) {\n" " if(!f(std::move(callback)))\n" " callback();\n" "}\n"); ASSERT_EQUALS("[test.cpp:4]: (warning) Access of moved variable 'callback'.\n", errout.str()); } void moveClassVariable() { check("struct B {\n" " virtual void f();\n" "};\n" "struct D : B {\n" " void f() override {\n" " auto p = std::unique_ptr(new D(std::move(m)));\n" " }\n" " D(std::unique_ptr c) : m(std::move(c)) {}\n" " std::unique_ptr m;\n" "};\n"); ASSERT_EQUALS("", errout.str()); } void forwardAndUsed() { Settings s = settingsBuilder().checkUnusedTemplates().build(); check("template\n" "void f(T && t) {\n" " g(std::forward(t));\n" " T s = t;\n" "}", &s); ASSERT_EQUALS("[test.cpp:4]: (warning) Access of forwarded variable 't'.\n", errout.str()); } void moveAndReference() { // #9791 check("void g(std::string&&);\n" "void h(const std::string&);\n" "void f() {\n" " std::string s;\n" " const std::string& r = s;\n" " g(std::move(s));\n" " h(r);\n" "}\n"); ASSERT_EQUALS("[test.cpp:7]: (warning) Access of moved variable 'r'.\n", errout.str()); } void moveForRange() { check("struct C {\n" " void f() {\n" " for (auto r : mCategory.find(std::move(mWhere))) {}\n" " }\n" " cif::category mCategory;\n" " cif::condition mWhere;\n" "};\n"); ASSERT_EQUALS("", errout.str()); } void funcArgNamesDifferent() { check("void func1(int a, int b, int c);\n" "void func1(int a, int b, int c) { }\n" "void func2(int a, int b, int c);\n" "void func2(int A, int B, int C) { }\n" "class Fred {\n" " void func1(int a, int b, int c);\n" " void func2(int a, int b, int c);\n" " void func3(int a = 0, int b = 0, int c = 0);\n" " void func4(int a = 0, int b = 0, int c = 0);\n" "};\n" "void Fred::func1(int a, int b, int c) { }\n" "void Fred::func2(int A, int B, int C) { }\n" "void Fred::func3(int a, int b, int c) { }\n" "void Fred::func4(int A, int B, int C) { }"); ASSERT_EQUALS("[test.cpp:3] -> [test.cpp:4]: (style, inconclusive) Function 'func2' argument 1 names different: declaration 'a' definition 'A'.\n" "[test.cpp:3] -> [test.cpp:4]: (style, inconclusive) Function 'func2' argument 2 names different: declaration 'b' definition 'B'.\n" "[test.cpp:3] -> [test.cpp:4]: (style, inconclusive) Function 'func2' argument 3 names different: declaration 'c' definition 'C'.\n" "[test.cpp:7] -> [test.cpp:12]: (style, inconclusive) Function 'func2' argument 1 names different: declaration 'a' definition 'A'.\n" "[test.cpp:7] -> [test.cpp:12]: (style, inconclusive) Function 'func2' argument 2 names different: declaration 'b' definition 'B'.\n" "[test.cpp:7] -> [test.cpp:12]: (style, inconclusive) Function 'func2' argument 3 names different: declaration 'c' definition 'C'.\n" "[test.cpp:9] -> [test.cpp:14]: (style, inconclusive) Function 'func4' argument 1 names different: declaration 'a' definition 'A'.\n" "[test.cpp:9] -> [test.cpp:14]: (style, inconclusive) Function 'func4' argument 2 names different: declaration 'b' definition 'B'.\n" "[test.cpp:9] -> [test.cpp:14]: (style, inconclusive) Function 'func4' argument 3 names different: declaration 'c' definition 'C'.\n", errout.str()); } void funcArgOrderDifferent() { check("void func1(int a, int b, int c);\n" "void func1(int a, int b, int c) { }\n" "void func2(int a, int b, int c);\n" "void func2(int c, int b, int a) { }\n" "void func3(int, int b, int c);\n" "void func3(int c, int b, int a) { }\n" "class Fred {\n" " void func1(int a, int b, int c);\n" " void func2(int a, int b, int c);\n" " void func3(int a = 0, int b = 0, int c = 0);\n" " void func4(int, int b = 0, int c = 0);\n" "};\n" "void Fred::func1(int a, int b, int c) { }\n" "void Fred::func2(int c, int b, int a) { }\n" "void Fred::func3(int c, int b, int a) { }\n" "void Fred::func4(int c, int b, int a) { }\n", nullptr, false); ASSERT_EQUALS("[test.cpp:3] -> [test.cpp:4]: (warning) Function 'func2' argument order different: declaration 'a, b, c' definition 'c, b, a'\n" "[test.cpp:5] -> [test.cpp:6]: (warning) Function 'func3' argument order different: declaration ', b, c' definition 'c, b, a'\n" "[test.cpp:9] -> [test.cpp:14]: (warning) Function 'func2' argument order different: declaration 'a, b, c' definition 'c, b, a'\n" "[test.cpp:10] -> [test.cpp:15]: (warning) Function 'func3' argument order different: declaration 'a, b, c' definition 'c, b, a'\n" "[test.cpp:11] -> [test.cpp:16]: (warning) Function 'func4' argument order different: declaration ', b, c' definition 'c, b, a'\n", errout.str()); } // #7846 - Syntax error when using C++11 braced-initializer in default argument void cpp11FunctionArgInit() { // syntax error is not expected ASSERT_NO_THROW(check("\n void foo(int declaration = {}) {" "\n for (int i = 0; i < 10; i++) {}\n" "\n }" "\n ")); ASSERT_EQUALS("", errout.str()); } void shadowVariables() { check("int x;\n" "void f() { int x; }"); ASSERT_EQUALS("[test.cpp:1] -> [test.cpp:2]: (style) Local variable \'x\' shadows outer variable\n", errout.str()); check("int x();\n" "void f() { int x; }"); ASSERT_EQUALS("[test.cpp:1] -> [test.cpp:2]: (style) Local variable \'x\' shadows outer function\n", errout.str()); check("struct C {\n" " C(int x) : x(x) {}\n" // <- we do not want a FP here " int x;\n" "};"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" " if (cond) {int x;}\n" // <- not a shadow variable " int x;\n" "}"); ASSERT_EQUALS("", errout.str()); check("int size() {\n" " int size;\n" // <- not a shadow variable "}"); ASSERT_EQUALS("", errout.str()); check("void f() {\n" // #8954 - lambda " int x;\n" " auto f = [](){ int x; }" "}"); ASSERT_EQUALS("", errout.str()); check("void f(int x) { int x; }"); ASSERT_EQUALS("[test.cpp:1] -> [test.cpp:1]: (style) Local variable 'x' shadows outer argument\n", errout.str()); check("class C { C(); void foo() { static int C = 0; } }"); // #9195 - shadow constructor ASSERT_EQUALS("", errout.str()); check("struct C {\n" // #10091 - shadow destructor " ~C();\n" " void f() {\n" " bool C{};\n" " }\n" "};\n" "C::~C() = default;"); ASSERT_EQUALS("", errout.str()); // 10752 - no check("struct S {\n" " int i;\n" "\n" " static int foo() {\n" " int i = 0;\n" " return i;\n" " }\n" "};"); ASSERT_EQUALS("", errout.str()); check("struct S {\n" " int i{};\n" " void f() { int i; }\n" "};\n"); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:3]: (style) Local variable 'i' shadows outer variable\n", errout.str()); check("struct S {\n" " int i{};\n" " std::vector v;\n" " void f() const { for (const int& i : v) {} }\n" "};\n"); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:4]: (style) Local variable 'i' shadows outer variable\n", errout.str()); check("struct S {\n" // #10405 " F* f{};\n" " std::list fl;\n" " void S::f() const;\n" "};\n" "void S::f() const {\n" " for (const F& f : fl) {}\n" "};\n"); ASSERT_EQUALS("[test.cpp:2] -> [test.cpp:7]: (style) Local variable 'f' shadows outer variable\n", errout.str()); check("extern int a;\n" "int a;\n" "static int f(void) {\n" " int a;\n" " return 0;\n" "}\n", "test.c"); ASSERT_EQUALS("[test.c:1] -> [test.c:4]: (style) Local variable 'a' shadows outer variable\n", errout.str()); } void knownArgument() { check("void g(int);\n" "void f(int x) {\n" " g((x & 0x01) >> 7);\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (style) Argument '(x&0x01)>>7' to function g is always 0. It does not matter what value 'x' has.\n", errout.str()); check("void g(int);\n" "void f(int x) {\n" " g((int)((x & 0x01) >> 7));\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (style) Argument '(int)((x&0x01)>>7)' to function g is always 0. It does not matter what value 'x' has.\n", errout.str()); check("void g(int);\n" "void f(int x) {\n" " g(0);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void g(int);\n" "void h() { return 1; }\n" "void f(int x) {\n" " g(h());\n" "}"); ASSERT_EQUALS("", errout.str()); check("void g(int);\n" "void f(int x) {\n" " g(std::strlen(\"a\"));\n" "}"); ASSERT_EQUALS("", errout.str()); check("void g(int);\n" "void f(int x) {\n" " g((int)0);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void g(Foo *);\n" "void f() {\n" " g(reinterpret_cast(0));\n" "}"); ASSERT_EQUALS("", errout.str()); check("void g(int);\n" "void f(int x) {\n" " x = 0;\n" " g(x);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void g(int);\n" "void f() {\n" " const int x = 0;\n" " g(x + 1);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void g(int);\n" "void f() {\n" " char i = 1;\n" " g(static_cast(i));\n" "}"); ASSERT_EQUALS("", errout.str()); check("char *yytext;\n" "void re_init_scanner() {\n" " int size = 256;\n" " yytext = xmalloc(size * sizeof *yytext);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void foo(const char *c) {\n" " if (*c == '+' && (operand || !isalnum(*c))) {}\n" "}"); ASSERT_EQUALS("", errout.str()); // #8986 check("void f(int);\n" "void g() {\n" " const int x[] = { 10, 10 };\n" " f(x[0]);\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(int);\n" "void g() {\n" " int x[] = { 10, 10 };\n" " f(x[0]);\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (style) Variable 'x' can be declared as const array\n", errout.str()); check("struct A { int x; };" "void g(int);\n" "void f(int x) {\n" " A y;\n" " y.x = 1;\n" " g(y.x);\n" "}"); ASSERT_EQUALS("", errout.str()); // allow known argument value in assert call check("void g(int);\n" "void f(int x) {\n" " ASSERT((int)((x & 0x01) >> 7));\n" "}"); ASSERT_EQUALS("", errout.str()); // #9905 - expression that does not use integer calculation at all check("void foo() {\n" " const std::string heading = \"Interval\";\n" " std::cout << std::setw(heading.length());\n" "}"); ASSERT_EQUALS("", errout.str()); // #9909 - struct member with known value check("struct LongStack {\n" " int maxsize;\n" "};\n" "\n" "void growLongStack(LongStack* self) {\n" " self->maxsize = 32;\n" " dostuff(self->maxsize * sizeof(intptr_t));\n" "}"); ASSERT_EQUALS("", errout.str()); // #11679 check("bool g(int);\n" "void h(int);\n" "int k(int a) { h(a); return 0; }\n" "void f(int i) {\n" " if (g(k(i))) {}\n" "}\n"); ASSERT_EQUALS("", errout.str()); } void knownArgumentHiddenVariableExpression() { // #9914 - variable expression is explicitly hidden check("void f(int x) {\n" " dostuff(x && false);\n" " dostuff(false && x);\n" " dostuff(x || true);\n" " dostuff(true || x);\n" " dostuff(x * 0);\n" " dostuff(0 * x);\n" "}\n"); ASSERT_EQUALS("[test.cpp:3]: (style) Argument 'false&&x' to function dostuff is always 0. Constant literal calculation disable/hide variable expression 'x'.\n" "[test.cpp:5]: (style) Argument 'true||x' to function dostuff is always 1. Constant literal calculation disable/hide variable expression 'x'.\n" "[test.cpp:6]: (style) Argument 'x*0' to function dostuff is always 0. Constant literal calculation disable/hide variable expression 'x'.\n" "[test.cpp:7]: (style) Argument '0*x' to function dostuff is always 0. Constant literal calculation disable/hide variable expression 'x'.\n", errout.str()); } void knownArgumentTernaryOperator() { // #10374 check("void f(bool a, bool b) {\n" " const T* P = nullptr; \n" " long N = 0; \n" " const bool c = foo(); \n" " bar(P, N); \n" " if (c ? a : b)\n" " baz(P, N); \n" "}"); ASSERT_EQUALS("", errout.str()); } void checkComparePointers() { check("int f() {\n" " const int foo[1] = {0};\n" " const int bar[1] = {0};\n" " int diff = 0;\n" " if(foo > bar) {\n" " diff = 1;\n" " }\n" " return diff;\n" "}"); ASSERT_EQUALS( "[test.cpp:2] -> [test.cpp:5] -> [test.cpp:3] -> [test.cpp:5] -> [test.cpp:5]: (error) Comparing pointers that point to different objects\n", errout.str()); check("bool f() {\n" " int x = 0;\n" " int y = 0;\n" " int* xp = &x;\n" " int* yp = &y;\n" " return xp > yp;\n" "}"); ASSERT_EQUALS( "[test.cpp:2] -> [test.cpp:4] -> [test.cpp:3] -> [test.cpp:5] -> [test.cpp:6]: (error) Comparing pointers that point to different objects\n" "[test.cpp:4]: (style) Variable 'xp' can be declared as pointer to const\n" "[test.cpp:5]: (style) Variable 'yp' can be declared as pointer to const\n", errout.str()); check("bool f() {\n" " int x = 0;\n" " int y = 1;\n" " return &x > &y;\n" "}"); ASSERT_EQUALS( "[test.cpp:2] -> [test.cpp:4] -> [test.cpp:3] -> [test.cpp:4] -> [test.cpp:4]: (error) Comparing pointers that point to different objects\n", errout.str()); check("struct A {int data;};\n" "bool f() {\n" " A x;\n" " A y;\n" " int* xp = &x.data;\n" " int* yp = &y.data;\n" " return xp > yp;\n" "}"); ASSERT_EQUALS( "[test.cpp:1] -> [test.cpp:5] -> [test.cpp:1] -> [test.cpp:6] -> [test.cpp:7]: (error) Comparing pointers that point to different objects\n" "[test.cpp:5]: (style) Variable 'xp' can be declared as pointer to const\n" "[test.cpp:6]: (style) Variable 'yp' can be declared as pointer to const\n", errout.str()); check("struct A {int data;};\n" "bool f(A ix, A iy) {\n" " A* x = &ix;\n" " A* y = &iy;\n" " int* xp = &x->data;\n" " int* yp = &y->data;\n" " return xp > yp;\n" "}"); ASSERT_EQUALS( "[test.cpp:2] -> [test.cpp:3] -> [test.cpp:5] -> [test.cpp:2] -> [test.cpp:4] -> [test.cpp:6] -> [test.cpp:7]: (error) Comparing pointers that point to different objects\n" "[test.cpp:5]: (style) Variable 'xp' can be declared as pointer to const\n" "[test.cpp:6]: (style) Variable 'yp' can be declared as pointer to const\n", errout.str()); check("bool f(int * xp, int* yp) {\n" " return &xp > &yp;\n" "}"); ASSERT_EQUALS( "[test.cpp:1] -> [test.cpp:2] -> [test.cpp:1] -> [test.cpp:2] -> [test.cpp:2]: (error) Comparing pointers that point to different objects\n", errout.str()); check("int f() {\n" " int x = 0;\n" " int y = 1;\n" " return &x - &y;\n" "}"); ASSERT_EQUALS( "[test.cpp:2] -> [test.cpp:4] -> [test.cpp:3] -> [test.cpp:4] -> [test.cpp:4]: (error) Subtracting pointers that point to different objects\n", errout.str()); check("bool f() {\n" " int x[2] = {1, 2}m;\n" " int* xp = &x[0];\n" " int* yp = &x[1];\n" " return xp > yp;\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (style) Variable 'xp' can be declared as pointer to const\n" "[test.cpp:4]: (style) Variable 'yp' can be declared as pointer to const\n", errout.str()); check("bool f(const int * xp, const int* yp) {\n" " return xp > yp;\n" "}"); ASSERT_EQUALS("", errout.str()); check("bool f(const int & x, const int& y) {\n" " return &x > &y;\n" "}"); ASSERT_EQUALS("", errout.str()); check("int& g();\n" "bool f() {\n" " const int& x = g();\n" " const int& y = g();\n" " const int* xp = &x;\n" " const int* yp = &y;\n" " return xp > yp;\n" "}"); ASSERT_EQUALS("", errout.str()); check("struct A {int data;};\n" "bool f(A ix) {\n" " A* x = &ix;\n" " A* y = x;\n" " int* xp = &x->data;\n" " int* yp = &y->data;\n" " return xp > yp;\n" "}"); ASSERT_EQUALS("[test.cpp:5]: (style) Variable 'xp' can be declared as pointer to const\n" "[test.cpp:6]: (style) Variable 'yp' can be declared as pointer to const\n", errout.str()); check("struct S { int i; };\n" // #11576 "int f(S s) {\n" " return &s.i - (int*)&s;\n" "}\n"); ASSERT_EQUALS("[test.cpp:3]: (style) C-style pointer casting\n", errout.str()); check("struct S { int i; };\n" "int f(S s1, S s2) {\n" " return &s1.i - reinterpret_cast(&s2);\n" "}\n"); ASSERT_EQUALS("[test.cpp:1] -> [test.cpp:3] -> [test.cpp:2] -> [test.cpp:3] -> [test.cpp:3]: (error) Subtracting pointers that point to different objects\n", errout.str()); } void unusedVariableValueTemplate() { check("#include \n" "class A\n" "{\n" "public:\n" " class Hash\n" " {\n" " public:\n" " std::size_t operator()(const A& a) const\n" " {\n" " (void)a;\n" " return 0;\n" " }\n" " };\n" "};\n" "namespace std\n" "{\n" " template <>\n" " struct hash\n" " {\n" " std::size_t operator()(const A& a) const noexcept\n" " {\n" " return A::Hash{}(a);\n" " }\n" " };\n" "}"); ASSERT_EQUALS("", errout.str()); } void moduloOfOne() { check("void f(unsigned int x) {\n" " int y = x % 1;\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (style) Modulo of one is always equal to zero\n", errout.str()); check("void f() {\n" " for (int x = 1; x < 10; x++) {\n" " int y = 100 % x;\n" " }\n" "}"); ASSERT_EQUALS("", errout.str()); check("void f(int i, int j) {\n" // #11191 " const int c = pow(2, i);\n" " if (j % c) {}\n" "}\n"); ASSERT_EQUALS("", errout.str()); } void sameExpressionPointers() { check("int f(int *i);\n" "void g(int *a, const int *b) {\n" " int c = *a;\n" " f(a);\n" " if (b && c != *a) {}\n" "}\n"); ASSERT_EQUALS("", errout.str()); } void checkOverlappingWrite() { // union check("void foo() {\n" " union { int i; float f; } u;\n" " u.i = 0;\n" " u.i = u.f;\n" // <- error "}"); ASSERT_EQUALS("[test.cpp:4]: (error) Overlapping read/write of union is undefined behavior\n", errout.str()); check("void foo() {\n" // #11013 " union { struct { uint8_t a; uint8_t b; }; uint16_t c; } u;\n" " u.a = u.b = 0;\n" "}"); ASSERT_EQUALS("", errout.str()); // memcpy check("void foo() {\n" " char a[10];\n" " memcpy(&a[5], &a[4], 2u);\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (error) Overlapping read/write in memcpy() is undefined behavior\n", errout.str()); check("void foo() {\n" " char a[10];\n" " memcpy(a+5, a+4, 2u);\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (error) Overlapping read/write in memcpy() is undefined behavior\n", errout.str()); check("void foo() {\n" " char a[10];\n" " memcpy(a, a+1, 2u);\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (error) Overlapping read/write in memcpy() is undefined behavior\n", errout.str()); check("void foo() {\n" " char a[8];\n" " memcpy(&a[0], &a[4], 4u);\n" "}"); ASSERT_EQUALS("", errout.str()); // wmemcpy check("void foo() {\n" " wchar_t a[10];\n" " wmemcpy(&a[5], &a[4], 2u);\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (error) Overlapping read/write in wmemcpy() is undefined behavior\n", errout.str()); check("void foo() {\n" " wchar_t a[10];\n" " wmemcpy(a+5, a+4, 2u);\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (error) Overlapping read/write in wmemcpy() is undefined behavior\n", errout.str()); check("void foo() {\n" " wchar_t a[10];\n" " wmemcpy(a, a+1, 2u);\n" "}"); ASSERT_EQUALS("[test.cpp:3]: (error) Overlapping read/write in wmemcpy() is undefined behavior\n", errout.str()); // strcpy check("void foo(char *ptr) {\n" " strcpy(ptr, ptr);\n" "}"); ASSERT_EQUALS("[test.cpp:2]: (error) Overlapping read/write in strcpy() is undefined behavior\n", errout.str()); } void constVariableArrayMember() { // #10371 check("class Foo {\n" "public:\n" " Foo();\n" " int GetVal() const { return m_Arr[0]; }\n" " int m_Arr[1];\n" "};\n"); ASSERT_EQUALS("", errout.str()); } }; REGISTER_TEST(TestOther)