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I have been looking for tools to help detect errors that prevent a program from running properly as 64-bit code. Most recently, I've been toying with Klocwork and its custom checkers feature, which lets me navigate the source code as a tree using XPath. This is useful as a "smarter" alternative to regular expressions, but I have not been able to make it aware of types.

For example, let's say I'd like to find every instance of a for loop that uses either an int or a long to count. The following code is easy to find.

for (int i = 0; i < 10; i++)
    // ...

Searching for this code is trivial because the variable definition is right inside the loop. However, consider the following example.

int i;
// ...
for (i = 0; i < 10; i++)
    // ...

This is difficult to find because the variable definition is separate from the loop, and the necessary XPath expression would be either unwieldy or bug-prone.

So, can custom Klocwork rules find expressions like this where type-awareness is necessary, including resolving typedef and #define statements? Are there other tools which can do this?

EDIT 1: Consider the following example.

typedef int myint;

void Foo() {
    int i;
    for (i = 0; i < 10; i++) {
        Bar();
    }

    myint j;
    for (j = 0; j < 10; j++) {
        Bar();
    }
}

The solution provided by ahmeddirie finds the first loop because the type of i is explicitly defined as int. The second loop is not found, however, because the typedef has obscured the underlying type. What tools keep track of types in a way that would identify the second loop variable j as indeed being an int?

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up vote 1 down vote accepted

Not entirely sure if this is what you want, but you can always resolve types quite easily with built-in functions. For example, answering your question (although perhaps not your underlying need):

//ForStmt / Init::ExprStmt / Expr::BinaryExpr [ $type := Left.getTypeName() ] [ $type = 'int' | $type.contains('long') ]

This will find ‘for’ loops that use ‘int’ or ‘long int’ counter types quite handily, and can obviously be applied to any element of an expression-based statement.

Type definitions are amenable to this kind of manipulation, whether programmer-defined or language-defined. Pre-processor definitions, however, will only yield their native language type (i.e. the macro itself isn’t available for manipulation via KAST, only what it expands to).

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Can you elaborate on how this works with typedef? I can see that I could manually add custom types to my expression, but is there any way to identify a type without explicitly including it? – Henry Merriam Jun 23 '11 at 19:33
1  
For the problem posed by OP, the key question that needs to be resolved is not the type of i, but whether the declaration/assignment of some i (e.g., the instance shown, note there might be several) is the for the same i as used in the for loop. You can't get this information directly from a syntax tree, if that is what Klocwork is offering. (You can get it indirectly by doing data flow analysis, but that can't reasonably be stated as an XPath expression). [You can't get the actual type of i, either, from a tree, but the poster's answer suggests KlocWork does provide it somehow] – Ira Baxter Jun 25 '11 at 2:57
    
Klocwork does seem able to correctly identify the type of i in the correct scope, and it sees #define directives. It does not, however, pay attention to typedef, so its utility to me is limited. I'm accepting this answer because it most directly helped me answer my question, but the other answers are also good because they answer the "or other tools" part of the title. – Henry Merriam Jun 26 '11 at 23:36

You can use Clang (http://clang.llvm.org) or even Elsa (https://github.com/dsw/oink-stack/) for generating an AST after a type propagation and templates instantiation. Both are providing a decent C++ API and some means for dumping an AST into a readable text. And both options are free.

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The company I work for, Semantic Designs Inc. provides tools incorporating a general infrastructure for analysis and transformation of programs and specific analysis components for various programming languages. Together these are known as DMS. In the case of C++, DMS includes integrated lexers, preprocessors, parsers, and name and type resolution components for each of GCC3, GCC4, ISO14882c1998 (ANSI), Visual C++ 6.0, and unmanaged Visual Studio 2005 C++. For various dialects of C, there also exist control flow analysis, a side effects analyzer, and a symbol dependency analyzer, with which tools like a pointer checker, deactive code remover, function profiler, and program slicer have been implemented.

The name and type resolution components provide complete symbol table information and look-up capabilities, so that references to identifiers can be readily associated with their types and other declarative information. The information is like that captured and used by a compiler, but is retained along with abstract syntax trees in a form amenable for adaptive re-use by any tool incorporating the component.

Semantic Designs recently built a custom tool that related specifically to the types of index variables in loop declarations, such as in your example. In this case the problem was to upgrade GCC2 code that used the -fno-for-scope compiler switch, which provided a scope resolution rule for loop variables that was not supported in later GCC dialects. The tool had to transform the loops, moving the declarations of their loop variables into an outer context that preserved the -fno-for-scope scoping rule. Where such changes were not necessary, no change was made.

Thus, the tool had to discern the type associated with each reference to a loop variable, differentiating in the case of masking scopes, and reconstruct the code so that GCC3 and GCC4 name resolution would result in the same semantic interpretation as the GCC2 with -fno-for-scope. This required being able to access the symbol table information associated with each variable reference, and in the case where code was being moved, to reconstruct the correct syntactic for of the type declaration for any variable whose declaration was moved. The symbol table and identifier reference table provided by the DMS C++ name and type resolution component contained all the required information, and a module for reconstructing prescribed type syntax allowed for the synthesis of correct new type declarations.

For example, consider the example:

// loop variable hides variable in global scope
// will change meaning without -fno-for-scope
// fix: move decl. of cnt before for-loop
//   optionally rename globcnt loop variable

float globcnt = 0.0;

int Foo::foo3() {
    for (int globcnt = 0; globcnt < 5; globcnt++) {
        globalInt += globcnt;
    }
    globalInt += 2*globcnt + 1;
    return 0;
}

GCC2 -fno-for-scope semantics indicate that the references to globcnt outside the loop are to the loop variable, even though GCC3 would consider the loop variable out of scope and resolve the references to the global variable. The tool transformed this code to:

float globcnt = 0.0;

int Foo::foo3() {
    int globcnt = 0;
    for (; globcnt < 5; globcnt++) {
        globalInt += globcnt;
    }
    globalInt += 2*globcnt + 1;
    return 0;
}

Had the code not been transformed, GCC4 would have always returned a value of 1 from Foo:foo3. Transformed, though, the value would have been influenced by the loop iterations as originally designed for GCC2. The tool had to recognize that the final reference to globcnt was to the local variable of type int, not to the global variable of type float, which it could do via symbol table lookup, and to act accordingly.

On the other hand, the tool recognized in the following code that there were no references to i outside the loop, so it was acceptable (and preferred) to leave the loop variable declaration intact.

int Foo::foo0() {
    for (int i = 0; i < 10; i++) {
        globalInt += i*i;
    }
    return 0;
}
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I have an answer to this question (which is very similar to the question in the other thread), but it's quite long. The format that is not really suitable for Stackoverflow. That's why I've written it as an article and posted in my blog. Here is the link: Detecting Overflows of 32-Bit Variables in Long Loops in 64-Bit Programs.

A fragment from the beginning of the article:

One of the problems that 64-bit software developers have to face is overflows of 32-bit variables in very long loops. PVS-Studio code analyzer is very good at catching issues of this type (see the Viva64 diagnostic set). A lot of questions concerning variable overflows are asked at StackOverflow.com. But since my answers may be treated as pure advertisement, rather than useful reference information, I decided to write an article where I could talk about PVS-Studio's capabilities.

A loop is a typical C/C++ construct. When porting software to the 64-bit architecture, loops suddenly become problem spots, as few developers think in advance what would happen if the program had to execute billions of iterations.

In our articles we call such issues 64-bit errors. Actually, these are simple errors. What makes them special is that they manifest themselves only in 64-bit applications. You simply don't have such long loops in 32-bit programs, and it's impossible to create an array of size larger than INT_MAX.

So, we've got a problem: 32-bit types overflow in a 64-bit program. 32-bit types include int, unsigned, and long (if you're working on Win64). We need to find a way to detect all such dangerous spots. The PVS-Studio analyzer can do it, and it is what we are going to talk about.

Let's discuss different scenarios of variable overflows occurring in long loops. continue...

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A link to a potential solution is always welcome, but please add context around the link so your fellow users will have some idea what it is and why it’s there. Always quote the most relevant part of an important link, in case the target site is unreachable or goes permanently offline. Take into account that being barely more than a link to an external site is a possible reason as to Why and how are some answers deleted?. – Tunaki Mar 22 at 9:19
    
While this link may answer the question, it is better to include the essential parts of the answer here and provide the link for reference. Link-only answers can become invalid if the linked page changes. - From Review – Mark Rotteveel Mar 22 at 9:33

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