ASSERT_EQUALS("[test.cpp:3]: (style) Obsolescent function 'usleep' called. It is recommended to use 'nanosleep' or 'setitimer' instead.\n",errout.str());
"}","test.cpp");// #4382 - there are no VLAs in C++
ASSERT_EQUALS("[test.cpp:3]: (warning) Obsolete function 'alloca' called. In C++11 and later it is recommended to use std::array<> instead.\n",errout.str());
check("void f()\n"
"{\n"
" char *x = alloca(10);\n"
"}","test.c");
ASSERT_EQUALS("[test.c:3]: (warning) Obsolete function 'alloca' called. In C99 and later it is recommended to use a variable length array instead.\n",errout.str());
settings.standards.c=Standards::C89;
settings.standards.cpp=Standards::CPP03;
check("void f()\n"
"{\n"
" char *x = alloca(10);\n"
"}","test.cpp");// #4382 - there are no VLAs in C++
ASSERT_EQUALS("[test.cpp:4]: (portability) Obsolescent function 'getcontext' called. Applications are recommended to be rewritten to use POSIX threads.\n",errout.str());
ASSERT_EQUALS("[test.cpp:3]: (warning) Return value of function crypt() is not used.\n"
"[test.cpp:3]: (portability) Non reentrant function 'crypt' called. For threadsafe applications it is recommended to use the reentrant replacement function 'crypt_r'.\n",errout.str());
ASSERT_EQUALS("[test.cpp:3]: (warning) Return value of function crypt() is not used.\n"
"[test.cpp:3]: (portability) Non reentrant function 'crypt' called. For threadsafe applications it is recommended to use the reentrant replacement function 'crypt_r'.\n",errout.str());
ASSERT_EQUALS("[test.cpp:3]: (portability) Non reentrant function 'localtime' called. For threadsafe applications it is recommended to use the reentrant replacement function 'localtime_r'.\n",errout.str());
// Passed as function argument
check("int f()\n"
"{\n"
" printf(\"Magic guess: %d\n\", getpwent());\n"
"}");
ASSERT_EQUALS("[test.cpp:3]: (portability) Non reentrant function 'getpwent' called. For threadsafe applications it is recommended to use the reentrant replacement function 'getpwent_r'.\n",errout.str());
// Pass return value
check("int f()\n"
"{\n"
" time_t t = 0;"
" struct tm *foo = localtime(&t);\n"
"}");
ASSERT_EQUALS("[test.cpp:3]: (portability) Non reentrant function 'localtime' called. For threadsafe applications it is recommended to use the reentrant replacement function 'localtime_r'.\n",errout.str());
ASSERT_EQUALS("[test.cpp:3]: (warning) Return value of function getpwent() is not used.\n"
"[test.cpp:3]: (portability) Non reentrant function 'getpwent' called. For threadsafe applications it is recommended to use the reentrant replacement function 'getpwent_r'.\n",errout.str());
ASSERT_EQUALS("[test.cpp:1]: (error) Invalid memset() argument nr 3. A non-boolean value is required.\n",errout.str());
check("int f() { memset(a,b,sizeof(a)!=0); }");
ASSERT_EQUALS("[test.cpp:1]: (error) Invalid memset() argument nr 3. A non-boolean value is required.\n",errout.str());
// Ticket #6588 (c mode)
check("void record(char* buf, int n) {\n"
" memset(buf, 0, n < 255);\n"/* KO */
" memset(buf, 0, n < 255 ? n : 255);\n"/* OK */
"}","test.c");
ASSERT_EQUALS("[test.c:2]: (error) Invalid memset() argument nr 3. A non-boolean value is required.\n",errout.str());
// Ticket #6588 (c++ mode)
check("void record(char* buf, int n) {\n"
" memset(buf, 0, n < 255);\n"/* KO */
" memset(buf, 0, n < 255 ? n : 255);\n"/* OK */
"}");
ASSERT_EQUALS("[test.cpp:2]: (error) Invalid memset() argument nr 3. A non-boolean value is required.\n",errout.str());
check("int f() { strtol(a,b,sizeof(a)!=12); }");
ASSERT_EQUALS("[test.cpp:1]: (error) Invalid strtol() argument nr 3. The value is 0 or 1 (comparison result) but the valid values are '0,2:36'.\n",errout.str());
check("int f() { strtol(a,b,1); }");
ASSERT_EQUALS("[test.cpp:1]: (error) Invalid strtol() argument nr 3. The value is 1 but the valid values are '0,2:36'.\n",errout.str());
check("int f() { strtol(a,b,10); }");
ASSERT_EQUALS("",errout.str());
}
voidmathfunctionCall_sqrt(){
// sqrt, sqrtf, sqrtl
check("void foo()\n"
"{\n"
" std::cout << sqrt(-1) << std::endl;\n"
" std::cout << sqrtf(-1) << std::endl;\n"
" std::cout << sqrtl(-1) << std::endl;\n"
"}");
ASSERT_EQUALS("[test.cpp:3]: (warning) Passing value -1 to sqrt() leads to implementation-defined result.\n"
"[test.cpp:4]: (warning) Passing value -1 to sqrtf() leads to implementation-defined result.\n"
"[test.cpp:5]: (warning) Passing value -1 to sqrtl() leads to implementation-defined result.\n",errout.str());
// implementation-defined behaviour for "finite values of x<0" only:
check("void foo()\n"
"{\n"
" std::cout << sqrt(-0.) << std::endl;\n"
" std::cout << sqrtf(-0.) << std::endl;\n"
" std::cout << sqrtl(-0.) << std::endl;\n"
"}");
ASSERT_EQUALS("",errout.str());
check("void foo()\n"
"{\n"
" std::cout << sqrt(1) << std::endl;\n"
" std::cout << sqrtf(1) << std::endl;\n"
" std::cout << sqrtl(1) << std::endl;\n"
"}");
ASSERT_EQUALS("",errout.str());
}
voidmathfunctionCall_log(){
// log,log10,logf,logl,log10f,log10l
check("void foo()\n"
"{\n"
" std::cout << log(-2) << std::endl;\n"
" std::cout << logf(-2) << std::endl;\n"
" std::cout << logl(-2) << std::endl;\n"
"}");
ASSERT_EQUALS("[test.cpp:3]: (warning) Passing value -2 to log() leads to implementation-defined result.\n"
"[test.cpp:4]: (warning) Passing value -2 to logf() leads to implementation-defined result.\n"
"[test.cpp:5]: (warning) Passing value -2 to logl() leads to implementation-defined result.\n",errout.str());
check("void foo()\n"
"{\n"
" std::cout << log(-1) << std::endl;\n"
" std::cout << logf(-1) << std::endl;\n"
" std::cout << logl(-1) << std::endl;\n"
"}");
ASSERT_EQUALS("[test.cpp:3]: (warning) Passing value -1 to log() leads to implementation-defined result.\n"
"[test.cpp:4]: (warning) Passing value -1 to logf() leads to implementation-defined result.\n"
"[test.cpp:5]: (warning) Passing value -1 to logl() leads to implementation-defined result.\n",errout.str());
check("void foo()\n"
"{\n"
" std::cout << log(-1.0) << std::endl;\n"
" std::cout << logf(-1.0) << std::endl;\n"
" std::cout << logl(-1.0) << std::endl;\n"
"}");
ASSERT_EQUALS("[test.cpp:3]: (warning) Passing value -1.0 to log() leads to implementation-defined result.\n"
"[test.cpp:4]: (warning) Passing value -1.0 to logf() leads to implementation-defined result.\n"
"[test.cpp:5]: (warning) Passing value -1.0 to logl() leads to implementation-defined result.\n",errout.str());
check("void foo()\n"
"{\n"
" std::cout << log(-0.1) << std::endl;\n"
" std::cout << logf(-0.1) << std::endl;\n"
" std::cout << logl(-0.1) << std::endl;\n"
"}");
ASSERT_EQUALS("[test.cpp:3]: (warning) Passing value -0.1 to log() leads to implementation-defined result.\n"
"[test.cpp:4]: (warning) Passing value -0.1 to logf() leads to implementation-defined result.\n"
"[test.cpp:5]: (warning) Passing value -0.1 to logl() leads to implementation-defined result.\n",errout.str());
check("void foo()\n"
"{\n"
" std::cout << log(0) << std::endl;\n"
" std::cout << logf(0.) << std::endl;\n"
" std::cout << logl(0.0) << std::endl;\n"
"}");
ASSERT_EQUALS("[test.cpp:3]: (warning) Passing value 0 to log() leads to implementation-defined result.\n"
"[test.cpp:4]: (warning) Passing value 0. to logf() leads to implementation-defined result.\n"
"[test.cpp:5]: (warning) Passing value 0.0 to logl() leads to implementation-defined result.\n",errout.str());
check("void foo()\n"
"{\n"
" std::cout << log(1E-3) << std::endl;\n"
" std::cout << logf(1E-3) << std::endl;\n"
" std::cout << logl(1E-3) << std::endl;\n"
" std::cout << log(1.0E-3) << std::endl;\n"
" std::cout << logf(1.0E-3) << std::endl;\n"
" std::cout << logl(1.0E-3) << std::endl;\n"
" std::cout << log(1.0E+3) << std::endl;\n"
" std::cout << logf(1.0E+3) << std::endl;\n"
" std::cout << logl(1.0E+3) << std::endl;\n"
" std::cout << log(2.0) << std::endl;\n"
" std::cout << logf(2.0) << std::endl;\n"
" std::cout << logf(2.0f) << std::endl;\n"
"}");
ASSERT_EQUALS("",errout.str());
check("void foo()\n"
"{\n"
" std::string *log(0);\n"
"}");
ASSERT_EQUALS("",errout.str());
// #3473 - no warning if "log" is a variable
check("Fred::Fred() : log(0) { }");
ASSERT_EQUALS("",errout.str());
// #5748
check("void f() { foo.log(0); }");
ASSERT_EQUALS("",errout.str());
}
voidmathfunctionCall_acos(){
// acos, acosf, acosl
check("void foo()\n"
"{\n"
" return acos(-1) \n"
" + acos(0.1) \n"
" + acos(0.0001) \n"
" + acos(0.01) \n"
" + acos(1.0E-1) \n"
" + acos(-1.0E-1) \n"
" + acos(+1.0E-1) \n"
" + acos(0.1E-1) \n"
" + acos(+0.1E-1) \n"
" + acos(-0.1E-1) \n"
" + acosf(-1) \n"
" + acosf(0.1) \n"
" + acosf(0.0001) \n"
" + acosf(0.01) \n"
" + acosf(1.0E-1) \n"
" + acosf(-1.0E-1) \n"
" + acosf(+1.0E-1) \n"
" + acosf(0.1E-1) \n"
" + acosf(+0.1E-1) \n"
" + acosf(-0.1E-1) \n"
" + acosl(-1) \n"
" + acosl(0.1) \n"
" + acosl(0.0001) \n"
" + acosl(0.01) \n"
" + acosl(1.0E-1) \n"
" + acosl(-1.0E-1) \n"
" + acosl(+1.0E-1) \n"
" + acosl(0.1E-1) \n"
" + acosl(+0.1E-1) \n"
" + acosl(-0.1E-1); \n"
"}");
ASSERT_EQUALS("",errout.str());
check("void foo()\n"
"{\n"
" std::cout << acos(1.1) << std::endl;\n"
" std::cout << acosf(1.1) << std::endl;\n"
" std::cout << acosl(1.1) << std::endl;\n"
"}");
ASSERT_EQUALS("[test.cpp:3]: (warning) Passing value 1.1 to acos() leads to implementation-defined result.\n"
"[test.cpp:4]: (warning) Passing value 1.1 to acosf() leads to implementation-defined result.\n"
"[test.cpp:5]: (warning) Passing value 1.1 to acosl() leads to implementation-defined result.\n",errout.str());
check("void foo()\n"
"{\n"
" std::cout << acos(-1.1) << std::endl;\n"
" std::cout << acosf(-1.1) << std::endl;\n"
" std::cout << acosl(-1.1) << std::endl;\n"
"}");
ASSERT_EQUALS("[test.cpp:3]: (warning) Passing value -1.1 to acos() leads to implementation-defined result.\n"
"[test.cpp:4]: (warning) Passing value -1.1 to acosf() leads to implementation-defined result.\n"
"[test.cpp:5]: (warning) Passing value -1.1 to acosl() leads to implementation-defined result.\n",errout.str());
}
voidmathfunctionCall_asin(){
// asin, asinf, asinl
check("void foo()\n"
"{\n"
" return asin(1) \n"
" + asin(-1) \n"
" + asin(0.1) \n"
" + asin(0.0001) \n"
" + asin(0.01) \n"
" + asin(1.0E-1) \n"
" + asin(-1.0E-1) \n"
" + asin(+1.0E-1) \n"
" + asin(0.1E-1) \n"
" + asin(+0.1E-1) \n"
" + asin(-0.1E-1) \n"
" + asinf(1) \n"
" + asinf(-1) \n"
" + asinf(0.1) \n"
" + asinf(0.0001) \n"
" + asinf(0.01) \n"
" + asinf(1.0E-1) \n"
" + asinf(-1.0E-1) \n"
" + asinf(+1.0E-1) \n"
" + asinf(0.1E-1) \n"
" + asinf(+0.1E-1) \n"
" + asinf(-0.1E-1) \n"
" + asinl(1) \n"
" + asinl(-1) \n"
" + asinl(0.1) \n"
" + asinl(0.0001) \n"
" + asinl(0.01) \n"
" + asinl(1.0E-1) \n"
" + asinl(-1.0E-1) \n"
" + asinl(+1.0E-1) \n"
" + asinl(0.1E-1) \n"
" + asinl(+0.1E-1) \n"
" + asinl(-0.1E-1); \n"
"}");
ASSERT_EQUALS("",errout.str());
check("void foo()\n"
"{\n"
" std::cout << asin(1.1) << std::endl;\n"
" std::cout << asinf(1.1) << std::endl;\n"
" std::cout << asinl(1.1) << std::endl;\n"
"}");
ASSERT_EQUALS("[test.cpp:3]: (warning) Passing value 1.1 to asin() leads to implementation-defined result.\n"
"[test.cpp:4]: (warning) Passing value 1.1 to asinf() leads to implementation-defined result.\n"
"[test.cpp:5]: (warning) Passing value 1.1 to asinl() leads to implementation-defined result.\n",errout.str());
check("void foo()\n"
"{\n"
" std::cout << asin(-1.1) << std::endl;\n"
" std::cout << asinf(-1.1) << std::endl;\n"
" std::cout << asinl(-1.1) << std::endl;\n"
"}");
ASSERT_EQUALS("[test.cpp:3]: (warning) Passing value -1.1 to asin() leads to implementation-defined result.\n"
"[test.cpp:4]: (warning) Passing value -1.1 to asinf() leads to implementation-defined result.\n"
"[test.cpp:5]: (warning) Passing value -1.1 to asinl() leads to implementation-defined result.\n",errout.str());
}
voidmathfunctionCall_pow(){
// pow, powf, powl
check("void foo()\n"
"{\n"
" std::cout << pow(0,-10) << std::endl;\n"
" std::cout << powf(0,-10) << std::endl;\n"
" std::cout << powl(0,-10) << std::endl;\n"
"}");
ASSERT_EQUALS("[test.cpp:3]: (warning) Passing values 0 and -10 to pow() leads to implementation-defined result.\n"
"[test.cpp:4]: (warning) Passing values 0 and -10 to powf() leads to implementation-defined result.\n"
"[test.cpp:5]: (warning) Passing values 0 and -10 to powl() leads to implementation-defined result.\n",errout.str());
check("void foo()\n"
"{\n"
" std::cout << pow(0,10) << std::endl;\n"
" std::cout << powf(0,10) << std::endl;\n"
" std::cout << powl(0,10) << std::endl;\n"
"}");
ASSERT_EQUALS("",errout.str());
}
voidmathfunctionCall_atan2(){
// atan2
check("void foo()\n"
"{\n"
" std::cout << atan2(1,1) ;\n"
" std::cout << atan2(-1,-1) ;\n"
" std::cout << atan2(0.1,1) ;\n"
" std::cout << atan2(0.0001,100) ;\n"
" std::cout << atan2(0.0,1e-1) ;\n"
" std::cout << atan2(1.0E-1,-3) ;\n"
" std::cout << atan2(-1.0E-1,+2) ;\n"
" std::cout << atan2(+1.0E-1,0) ;\n"
" std::cout << atan2(0.1E-1,3) ;\n"
" std::cout << atan2(+0.1E-1,1) ;\n"
" std::cout << atan2(-0.1E-1,8) ;\n"
" std::cout << atan2f(1,1) ;\n"
" std::cout << atan2f(-1,-1) ;\n"
" std::cout << atan2f(0.1,1) ;\n"
" std::cout << atan2f(0.0001,100) ;\n"
" std::cout << atan2f(0.0,1e-1) ;\n"
" std::cout << atan2f(1.0E-1,-3) ;\n"
" std::cout << atan2f(-1.0E-1,+2) ;\n"
" std::cout << atan2f(+1.0E-1,0) ;\n"
" std::cout << atan2f(0.1E-1,3) ;\n"
" std::cout << atan2f(+0.1E-1,1) ;\n"
" std::cout << atan2f(-0.1E-1,8) ;\n"
" std::cout << atan2l(1,1) ;\n"
" std::cout << atan2l(-1,-1) ;\n"
" std::cout << atan2l(0.1,1) ;\n"
" std::cout << atan2l(0.0001,100) ;\n"
" std::cout << atan2l(0.0,1e-1) ;\n"
" std::cout << atan2l(1.0E-1,-3) ;\n"
" std::cout << atan2l(-1.0E-1,+2) ;\n"
" std::cout << atan2l(+1.0E-1,0) ;\n"
" std::cout << atan2l(0.1E-1,3) ;\n"
" std::cout << atan2l(+0.1E-1,1) ;\n"
" std::cout << atan2l(-0.1E-1,8) ;\n"
"}");
ASSERT_EQUALS("",errout.str());
check("void foo()\n"
"{\n"
" std::cout << atan2(0,0) << std::endl;\n"
" std::cout << atan2f(0,0) << std::endl;\n"
" std::cout << atan2l(0,0) << std::endl;\n"
"}");
ASSERT_EQUALS("[test.cpp:3]: (warning) Passing values 0 and 0 to atan2() leads to implementation-defined result.\n"
"[test.cpp:4]: (warning) Passing values 0 and 0 to atan2f() leads to implementation-defined result.\n"
"[test.cpp:5]: (warning) Passing values 0 and 0 to atan2l() leads to implementation-defined result.\n",errout.str());
}
voidmathfunctionCall_fmod(){
// fmod, fmodl, fmodf
check("void foo()\n"
"{\n"
" std::cout << fmod(1.0,0) << std::endl;\n"
" std::cout << fmodf(1.0,0) << std::endl;\n"
" std::cout << fmodl(1.0,0) << std::endl;\n"
"}");
ASSERT_EQUALS("[test.cpp:3]: (warning) Passing values 1.0 and 0 to fmod() leads to implementation-defined result.\n"
"[test.cpp:4]: (warning) Passing values 1.0 and 0 to fmodf() leads to implementation-defined result.\n"
"[test.cpp:5]: (warning) Passing values 1.0 and 0 to fmodl() leads to implementation-defined result.\n",errout.str());
check("void foo()\n"
"{\n"
" std::cout << fmod(1.0,1) << std::endl;\n"
" std::cout << fmodf(1.0,1) << std::endl;\n"
" std::cout << fmodl(1.0,1) << std::endl;\n"
"}");
ASSERT_EQUALS("",errout.str());
}
voidmathfunctionCall_precision(){
check("void foo() {\n"
" print(exp(x) - 1);\n"
" print(log(1 + x));\n"
" print(1 - erf(x));\n"
"}");
ASSERT_EQUALS("[test.cpp:2]: (style) Expression 'exp(x) - 1' can be replaced by 'expm1(x)' to avoid loss of precision.\n"
"[test.cpp:3]: (style) Expression 'log(1 + x)' can be replaced by 'log1p(x)' to avoid loss of precision.\n"
"[test.cpp:4]: (style) Expression '1 - erf(x)' can be replaced by 'erfc(x)' to avoid loss of precision.\n",errout.str());
check("void foo() {\n"
" print(exp(x) - 1.0);\n"
" print(log(1.0 + x));\n"
" print(1.0 - erf(x));\n"
"}");
ASSERT_EQUALS("[test.cpp:2]: (style) Expression 'exp(x) - 1' can be replaced by 'expm1(x)' to avoid loss of precision.\n"
"[test.cpp:3]: (style) Expression 'log(1 + x)' can be replaced by 'log1p(x)' to avoid loss of precision.\n"
"[test.cpp:4]: (style) Expression '1 - erf(x)' can be replaced by 'erfc(x)' to avoid loss of precision.\n",errout.str());
check("void foo() {\n"
" print(exp(3 + x*f(a)) - 1);\n"
" print(log(x*4 + 1));\n"
" print(1 - erf(34*x + f(x) - c));\n"
"}");
ASSERT_EQUALS("[test.cpp:2]: (style) Expression 'exp(x) - 1' can be replaced by 'expm1(x)' to avoid loss of precision.\n"
"[test.cpp:3]: (style) Expression 'log(1 + x)' can be replaced by 'log1p(x)' to avoid loss of precision.\n"
"[test.cpp:4]: (style) Expression '1 - erf(x)' can be replaced by 'erfc(x)' to avoid loss of precision.\n",errout.str());
check("void foo() {\n"
" print(2*exp(x) - 1);\n"
" print(1 - erf(x)/2.0);\n"
"}");
ASSERT_EQUALS("",errout.str());
}
voidcheckIgnoredReturnValue(){
Settingssettings2;
settings2.addEnabled("warning");
constcharxmldata[]="<?xml version=\"1.0\"?>\n"
"<def version=\"2\">\n"
" <function name=\"mystrcmp,foo::mystrcmp\">\n"
" <use-retval/>\n"
" <arg nr=\"1\"/>\n"
" <arg nr=\"2\"/>\n"
" </function>\n"
"</def>";
tinyxml2::XMLDocumentdoc;
doc.Parse(xmldata,sizeof(xmldata));
settings2.library.load(doc);
check("void foo() {\n"
" mystrcmp(a, b);\n"
"}","test.cpp",&settings2);
ASSERT_EQUALS("[test.cpp:2]: (warning) Return value of function mystrcmp() is not used.\n",errout.str());
check("void foo() {\n"
" foo::mystrcmp(a, b);\n"
"}","test.cpp",&settings2);
ASSERT_EQUALS("[test.cpp:2]: (warning) Return value of function mystrcmp() is not used.\n",errout.str());
check("bool mystrcmp(char* a, char* b);\n"// cppcheck sees a custom strcmp definition, but it returns a value. Assume it is the one specified in the library.
"void foo() {\n"
" mystrcmp(a, b);\n"
"}","test.cpp",&settings2);
ASSERT_EQUALS("[test.cpp:3]: (warning) Return value of function mystrcmp() is not used.\n",errout.str());
check("void mystrcmp(char* a, char* b);\n"// cppcheck sees a custom strcmp definition which returns void!
"void foo() {\n"
" mystrcmp(a, b);\n"
"}","test.cpp",&settings2);
ASSERT_EQUALS("",errout.str());
check("void foo() {\n"
" class mystrcmp { mystrcmp() {} };\n"// strcmp is a constructor definition here