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There are many options for static analysis, and it's a hot topic, so:

What is static analysis?

When should you use it, and when shouldn't it be used?

What are potential gotchas regarding proper and improper usage/application of static analysis?

Any languages that don't have a good static analysis tool, and what do you do when you don't have an option for automated analysis?

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8 Answers 8

up vote 28 down vote accepted

What is static analysis?

Analyzing code without executing it. Generally used to find bugs or ensure conformance to coding guidelines. The classic example is a compiler which finds lexical, syntactic and even some semantic mistakes.

When should you use it, and when shouldn't it be used?

Static analysis tools should be used when they help maintain code quality. If they're used, they should be integrated into the build process, otherwise they will be ignored.

What are potential gotchas regarding proper and improper usage/application of static analysis?

Two common pathologies occur when using static analysis tools:

  1. The tools produces spurious warnings/errors that the developers cannot silence. Eventually, most of the warnings are spurious and the developers stop paying attention to the output. This is why many teams require that code compile cleanly. If developers feel comfortable ignoring compiler warnings, the compile phase will eventually be filled with warning nobody ever pays attention to, even though they may be bugs.

  2. The tools take too long to run and developers never bother to run them.

Any languages that don't have a good static analysis tool, and what do you do when you don't have an option for automated analysis?

For a number of reasons, many of the dynamic languages (ruby, python, perl) don't have static analysis tools that are as strong as those available in static languages. The standard method of finding bugs and making sure the code is working in dynamic languages are unit tests which help build confidence that the code actually works (hat-tip: Chris Conway).

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"unit tests which (theoretically) prove that the code actually works." Not to be a pedant (oh, OK, to be a pedant), unit tests don't "prove" anything, not even "theoretically." Tests build confidence in correctness, but they can't possibly cover every behavior of the –  Chris Conway Sep 8 '08 at 14:16
    
"they should be integrated into the build process" agreed. However, debug and release builds, or one or the other? –  scottmarlowe Sep 1 '09 at 15:23
    
@ChrisConway Untrue; if you use systematic proofs or pre/post conditions to narrow a given partial or total function down, you can use unit tests to exhaustively prove those cases (and therefore have an inductive proof that the code does what it says it does). While this is not easy for many large scale or worth while functions, it is surely possible, both theoretically and practically. –  Alice Aug 11 at 1:15

Static code analysis is the process of detecting errors and defects in software's source code. Static analysis can be viewed as an automated code review process. Let's speak on the code review now.

Code review is one of the oldest and safest methods of defect detection. It deals with joint attentive reading of the source code and giving recommendations on how to improve it. This process reveals errors or code fragments that can become errors in future. It is also considered that the code's author should not give explanations on how a certain program part works. The program's execution algorithm should be clear directly from the program text and comments. If it is not so, the code needs improving.

The code review usually works well because programmers can notice errors in somebody else's code much easier than in their own's. To learn more about the code review method, please see a wonderful book "Code Complete" by Steve McConnell (1).

The only crucial disadvantage of the joint code review method is an extremely high price: you need to gather several programmers at regular times to review a fresh code or re-review a code after recommended changes have been applied to it. The programmers also need to have a rest regularly, as their attention might quickly weaken if they review large code fragments at a time, so there will be no use of code review then.

It appears that - on the one hand - you want to review your code regularly. On the other hand, it is too expensive. Static code analysis tools are a compromise solution. They can tirelessly handle source texts of programs and give recommendations to the programmer on what code fragments he/she should consider. Of course, a program can never replace complete code review performed by a team of programmers, but the ratio use/price makes usage of static analysis a rather good practice exploited by many companies.

The tasks solved by static code analysis software can be divided into 3 categories:

  1. Detecting errors in programs. We will speak on that in detail further.
  2. Recommendations on code formatting. Some static analyzers allow you to check if the source code corresponds to the code formatting standard accepted in your company. We mean control of the number of indents in various constructs, use of spaces/tabs and so on.
  3. Metrics computation. Software metrics are a measure that lets you get a numerical value of some property of software or its specifications. There are lots of various metrics that can be computed with the help of certain tools.

There are also other ways of using static code analysis tools. For instance, static analysis can be used as a method to control and teach new workers who are not yet familiar enough with the company's programming rules.

There are a lot of commercial and free static code analyzers. The Wikipedia website contains a large list of static analyzers: List of tools for static code analysis. The list of languages static code analyzers support is great too (C, C++, C#, Java, Ada, Fortran, Perl, Ruby, ...).

Like any other error detection methodology, static analysis has its strong and weak points. You should understand that there are no ideal software testing methods. Different methods will produce different results for different software classes. Only combining various methods will enable you to achieve the highest quality of your software.

The main advantage of static analysis is this: it enables you to greatly reduce the price of eliminating defects in software. The earlier an error is detected, the lower the price to fix it. Thus, according to the data given in the book "Code Complete" by McConnell, fixing an error at the stage of testing costs ten times more than at the code writing stage:

enter image description here Figure 1. An average cost of fixing defects depending on the time they have been made and detected (the data for the table are taken from the book "Code Complete" by S. McConnell).

Static analysis tools allow you to quickly detect a lot of errors of the coding stage, which significantly reduces the cost of development of the whole project. For example, the PVS-Studio static code analyzer can run in background right after compilation is done and tell the programmer about potential errors if there are any (see incremental analysis mode).

Other static code analysis' advantages are the following:

  1. Full code coverage. Static analyzers check even those code fragments that get control very rarely. These code fragments usually cannot be tested through other methods. It allows you to find defects in exception handlers or in the logging system.
  2. Static analysis doesn't depend on the compiler you are using and the environment where the compiled program will be executed. It allows you to find hidden errors that can reveal themselves only a few years later. For instance, these are undefined behavior errors. Such errors can occur when switching to another compiler version or when using other code optimization switches. Another interesting example of hidden errors is discussed in the article "Overwriting memory - why?".
  3. You can easily and quickly detect misprints and consequences of Copy-Paste usage. Detecting these errors through other methods is usually a too inefficient waste of time and efforts. It's a pity when you have spent an hour on debugging just to find out that the error is in an expression of the "strcmp(A, A)"-kind. People usually don't remember such troubles when discussing typical errors. But practice shows that it takes much time to detect them.

Static code analysis' disadvantages

  1. Static analysis is usually poor regarding diagnosing memory leaks and concurrency errors. To detect such errors you actually need to execute a part of the program virtually. It is too difficult to implement. Such algorithms take too much memory and processor time. Static analyzers usually limit themselves to diagnosing simple cases. A more efficient way to detect memory leaks and concurrency errors is to use dynamic analysis tools.
  2. A static analysis tool warns you about odd fragments. It means that the code can actually be quite correct. It is called false-positive reports. Only the programmer can understand if the analyzer points to a real error or it is just a false positive. The necessity to review false positives takes work time and weakens attention to those code fragments that really contain errors.

Errors detected by static analyzers are rather diverse. Here is, for example, the list of diagnostics implemented in the PVS-Studio tool. Some analyzers focus on a certain area or type of defects, while others support certain coding standards, for instance, MISRA-C:1998, MISRA-C:2004, Sutter-Alexandrescu Rules, Meyers-Klaus Rules, etc.

The sphere of static analysis is actively developing; new diagnostic rules and standards appear, while some rules get obsolete. That's why there is no sense in trying to compare analyzers on the basis of defects they can detect. The only way to compare tools is to check them on a set of projects and count the number of real errors they have found. This subject is discussed in detail in the article "Difficulties of comparing code analyzers, or don't forget about usability".

Examples of errors detected by static code analysis

  1. 90 errors in the open-source projects;
  2. PVS-Studio vs Chromium;
  3. PVS-Studio: analyzing Doom 3 code;
  4. PVS-Studio vs Clang;
  5. Intel IPP Samples for Windows - error correction.

Myths about static analysis

  1. The first myth. A static analyzer is a single-use product;
  2. The second myth. Expert developers do not make silly mistakes;
  3. The third myth. Dynamic analysis is better than static analysis;
  4. The fourth myth. Programmers want to add their own rules into a static analyzer;
  5. The fifth myth. A small test program is enough to evaluate a tool.

References

  1. Steve McConnell, "Code Complete, 2nd Edition" Microsoft Press, Paperback, 2nd edition, Published June 2004, 914 pages, ISBN: 0-7356-1967-0.
  2. Wikipedia. Static code analysis.
  3. Coverity. A Few Billion Lines of Code Later: Using Static Analysis to Find Bugs in the Real World.
  4. By Walter W. Schilling, Jr. and Mansoor Alam. "Integrate static analysis into a software development process".
  5. Criticism. Mark Dixon. Top five reasons not to use static analysis.
  6. John Carmack. Static Code Analysis.
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Other questions on static analysis (each with tool recommendations):

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Static analysis is looking at source-code for potential problems. It's called static because the code isn't executed to find the problems, the source is analysed analytically.

At the moment, static analysis is very immature. Most tools find only the most stupid of bugs. For example, no tools that I know of can find all null pointer dereferences, yet this is an obvious bug you'd want to target with static analysis. You can forget trying to find harder bugs such as race conditions with static analysis, for the moment at least.

Static Analysis is particularly useful for enforcing coding standards. FXCop, which analyses .NET code, contains rules for all sorts of coding standards defects.

As you say, there are many tools that do static analysis. Here is a list of free products that I have personally used:

  • FindBugs (Java)
  • FXCop (.NET)
  • PyLint (Python)

I can recommend all of them.

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Static analysis needn't actually look at the source code. It may well look at object or intermediate code. For instance, you mention FindBugs which looks at class (bytecode) files. –  Tom Hawtin - tackline Sep 8 '08 at 14:56
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Static analysis, immature? I see you never used IntelliJ IDEA... ;^) –  Rogério Aug 12 '09 at 2:44
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Yes, Tom Reps gave a talk last week at Stanford on static analysis of machine code, cs.wisc.edu/wpis/abstracts/wysinwyx.submission.abs.html. For an example of a vulnerability not visible in source, see <isc.sans.org/diary.html?storyid=6820>;, <linux-magazine.com/Online/News/…;, <blogs.computerworld.com/a_linux_security_story>;, and <lwn.net/Articles/341773/>;. –  Flash Sheridan Sep 2 '09 at 4:55
    
@Flash - I had Prof. Reps for a compilers class, very interesting guy. Great comment, thanks for the info. –  twopoint718 Aug 9 '11 at 2:22

Check out http://www.ouncelabs.com if you are looking for an enterprise class tool.

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What is static analysis?

Static analysis allows us to reason about all possible executions of a program. It gives assurance about any execution, prior to deployment but commercial tools spend a lot of effort dealing with developer confusion, false positives, etc

What are potential gotchas regarding proper and improper usage/application of static analysis?

Main issue is abstraction. Abstraction lets us scale and model all possible runs but must be conservative, trying to balance precision and scalability. Static analysis abstractions do not cleanly match developer abstractions

When should you use it, and when shouldn't it be used?

Main purpose is for code testing and maintenance as it fits well with developer intuitions. In practice, its the most common form of bug-detection but each test explores only one possible execution of the system. Developers who are in the security industry use this as a main tool for exploring code bugs, exploits, etc.

Here is an example of Static analysis using Symbolic execution where the key idea is to generalize testing by using unknown symbolic variables in evaluation where we track symbolic states. If execution path depends on unknown, we fork symbolic executor.During symbolic execution, we are trying to determine if certain formulas are satisfiable (e.g. is a particular program point reachable, is array access A[i] out of bounds? etc).

int a = α, b = β, c = γ;
// symbolic
int x = 0, y = 0, z = 0;
if (a) {
   x = -2;
}
if (b < 5) {
   if (!a && c) { y = 1; }
   z = 2;
}
assert(x+y+z!=3)

And the analysis of this simple code sample: Static code Analysis

Here are some useful links for SMT/SAT solvers that are used for static code analysis:

SAT solving, SMT solving and Program Verification

List of tools for Static Code Analysis

Symbolic Execution

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In addition to finding bugs in your code (such as guaranteed null pointer dereferencing, infinite loops, etc.), static analysis can be used for security analysis of the code. I'd highly recommend watching the "Secure Programming with Static Analysis" presentation from Brian Chess of Fortify software.

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Static analysis (also known as static code analysis, source code analysis, static program analysis) is a software verification activity in which source code is analyzed for quality, safety, and security. This analysis enables software developers and testers to identify and diagnose various types of bugs/errors such as overflows, divide by zero, memory and pointer errors, run-time errors, and other issues.

Metrics produced by static code analysis provide a means by which software quality can be measured and improved. In contrast to other verification techniques, static analysis is automated, and can therefore be done without executing the program or developing test cases.

Sophisticated techniques couple static code analysis with formal methods. Formal methods apply theoretical computer science fundamentals to solve difficult problems in software, such as proving that the software will not fail with a run-time error. The combination of static code analysis and formal methods enables developers to detect difficult to find errors and prove the absence of certain types of bugs/errors. E.g. these techniques can prove that the following line of code will never fail with a divide by zero run-time error:

int x, y;
...
x = x / (x - y);

In general, static analysis should be used early in the development process, preferably before unit test. This enables development of robust code. Static analysis can also be coupled with build systems to produce quality metrics and provide guidance about the safety and reliability of the software. However, late use of static analysis in general may require more time and resource to address identified issues.

A variety of open source, academic, and commercial static analysis tools are available. Most languages are supported. Learn more about this topic at the following links

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