1f51a89d39
These were ignored by git accidentally. We want ALL OF THEM since they all came in the llvm/clang source distribution.
347 lines
14 KiB
HTML
347 lines
14 KiB
HTML
<!DOCTYPE HTML PUBLIC "-//W3C//DTD HTML 4.01//EN"
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"http://www.w3.org/TR/html4/strict.dtd">
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<html>
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<head>
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<title>Checker Developer Manual</title>
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<link type="text/css" rel="stylesheet" href="menu.css">
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<link type="text/css" rel="stylesheet" href="content.css">
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<script type="text/javascript" src="scripts/menu.js"></script>
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</head>
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<body>
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<div id="page">
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<!--#include virtual="menu.html.incl"-->
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<div id="content">
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<h1 style="color:red">This Page Is Under Construction</h1>
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<h1>Checker Developer Manual</h1>
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<p>The static analyzer engine performs symbolic execution of the program and
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relies on a set of checkers to implement the logic for detecting and
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constructing bug reports. This page provides hints and guidelines for anyone
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who is interested in implementing their own checker. The static analyzer is a
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part of the Clang project, so consult <a href="http://clang.llvm.org/hacking.html">Hacking on Clang</a>
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and <a href="http://llvm.org/docs/ProgrammersManual.html">LLVM Programmer's Manual</a>
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for general developer guidelines and information. </p>
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<ul>
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<li><a href="#start">Getting Started</a></li>
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<li><a href="#analyzer">Analyzer Overview</a></li>
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<li><a href="#idea">Idea for a Checker</a></li>
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<li><a href="#registration">Checker Registration</a></li>
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<li><a href="#skeleton">Checker Skeleton</a></li>
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<li><a href="#node">Exploded Node</a></li>
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<li><a href="#bugs">Bug Reports</a></li>
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<li><a href="#ast">AST Visitors</a></li>
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<li><a href="#testing">Testing</a></li>
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<li><a href="#commands">Useful Commands</a></li>
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</ul>
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<h2 id=start>Getting Started</h2>
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<ul>
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<li>To check out the source code and build the project, follow steps 1-4 of
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the <a href="http://clang.llvm.org/get_started.html">Clang Getting Started</a>
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page.</li>
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<li>The analyzer source code is located under the Clang source tree:
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<br><tt>
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$ <b>cd llvm/tools/clang</b>
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</tt>
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<br>See: <tt>include/clang/StaticAnalyzer</tt>, <tt>lib/StaticAnalyzer</tt>,
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<tt>test/Analysis</tt>.</li>
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<li>The analyzer regression tests can be executed from the Clang's build
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directory:
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<br><tt>
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$ <b>cd ../../../; cd build/tools/clang; TESTDIRS=Analysis make test</b>
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</tt></li>
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<li>Analyze a file with the specified checker:
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<br><tt>
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$ <b>clang -cc1 -analyze -analyzer-checker=core.DivideZero test.c</b>
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</tt></li>
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<li>List the available checkers:
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<br><tt>
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$ <b>clang -cc1 -analyzer-checker-help</b>
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</tt></li>
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<li>See the analyzer help for different output formats, fine tuning, and
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debug options:
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<br><tt>
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$ <b>clang -cc1 -help | grep "analyzer"</b>
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</tt></li>
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</ul>
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<h2 id=analyzer>Static Analyzer Overview</h2>
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The analyzer core performs symbolic execution of the given program. All the
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input values are represented with symbolic values; further, the engine deduces
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the values of all the expressions in the program based on the input symbols
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and the path. The execution is path sensitive and every possible path through
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the program is explored. The explored execution traces are represented with
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<a href="http://clang.llvm.org/doxygen/classclang_1_1ento_1_1ExplodedGraph.html">ExplidedGraph</a> object.
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Each node of the graph is
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<a href="http://clang.llvm.org/doxygen/classclang_1_1ento_1_1ExplodedNode.html">ExplodedNode</a>,
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which consists of a <tt>ProgramPoint</tt> and a <tt>ProgramState</tt>.
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<p>
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<a href="http://clang.llvm.org/doxygen/classclang_1_1ProgramPoint.html">ProgramPoint</a>
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represents the corresponding location in the program (or the CFG graph).
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<tt>ProgramPoint</tt> is also used to record additional information on
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when/how the state was added. For example, <tt>PostPurgeDeadSymbolsKind</tt>
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kind means that the state is the result of purging dead symbols - the
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analyzer's equivalent of garbage collection.
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<p>
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<a href="http://clang.llvm.org/doxygen/classclang_1_1ento_1_1ProgramState.html">ProgramState</a>
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represents abstract state of the program. It consists of:
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<ul>
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<li><tt>Environment</tt> - a mapping from source code expressions to symbolic
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values
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<li><tt>Store</tt> - a mapping from memory locations to symbolic values
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<li><tt>GenericDataMap</tt> - constraints on symbolic values
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</ul>
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<h3>Interaction with Checkers</h3>
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Checkers are not merely passive receivers of the analyzer core changes - they
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actively participate in the <tt>ProgramState</tt> construction through the
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<tt>GenericDataMap</tt> which can be used to store the checker-defined part
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of the state. Each time the analyzer engine explores a new statement, it
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notifies each checker registered to listen for that statement, giving it an
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opportunity to either report a bug or modify the state. (As a rule of thumb,
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the checker itself should be stateless.) The checkers are called one after another
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in the predefined order; thus, calling all the checkers adds a chain to the
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<tt>ExplodedGraph</tt>.
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<h3>Representing Values</h3>
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During symbolic execution, <a href="http://clang.llvm.org/doxygen/classclang_1_1ento_1_1SVal.html">SVal</a>
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objects are used to represent the semantic evaluation of expressions. They can
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represent things like concrete integers, symbolic values, or memory locations
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(which are memory regions). They are a discriminated union of "values",
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symbolic and otherwise.
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<p>
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<a href="http://clang.llvm.org/doxygen/classclang_1_1ento_1_1SymExpr.html">SymExpr</a> (symbol)
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is meant to represent abstract, but named, symbolic value.
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Symbolic values can have constraints associated with them. Symbols represent
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an actual (immutable) value. We might not know what its specific value is, but
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we can associate constraints with that value as we analyze a path.
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<p>
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<a href="http://clang.llvm.org/doxygen/classclang_1_1ento_1_1MemRegion.html">MemRegion</a> is similar to a symbol.
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It is used to provide a lexicon of how to describe abstract memory. Regions can
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layer on top of other regions, providing a layered approach to representing memory.
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For example, a struct object on the stack might be represented by a <tt>VarRegion</tt>,
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but a <tt>FieldRegion</tt> which is a subregion of the <tt>VarRegion</tt> could
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be used to represent the memory associated with a specific field of that object.
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So how do we represent symbolic memory regions? That's what <a href="http://clang.llvm.org/doxygen/classclang_1_1ento_1_1SymbolicRegion.html">SymbolicRegion</a>
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is for. It is a <tt>MemRegion</tt> that has an associated symbol. Since the
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symbol is unique and has a unique name; that symbol names the region.
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<p>
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Let's see how the analyzer processes the expressions in the following example:
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<p>
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<pre class="code_example">
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int foo(int x) {
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int y = x * 2;
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int z = x;
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...
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}
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</pre>
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<p>
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Let's look at how <tt>x*2</tt> gets evaluated. When <tt>x</tt> is evaluated,
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we first construct an <tt>SVal</tt> that represents the lvalue of <tt>x</tt>, in
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this case it is an <tt>SVal</tt> that references the <tt>MemRegion</tt> for <tt>x</tt>.
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Afterwards, when we do the lvalue-to-rvalue conversion, we get a new <tt>SVal</tt>,
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which references the value <b>currently bound</b> to <tt>x</tt>. That value is
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symbolic; it's whatever <tt>x</tt> was bound to at the start of the function.
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Let's call that symbol <tt>$0</tt>. Similarly, we evaluate the expression for <tt>2</tt>,
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and get an <tt>SVal</tt> that references the concrete number <tt>2</tt>. When
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we evaluate <tt>x*2</tt>, we take the two <tt>SVals</tt> of the subexpressions,
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and create a new <tt>SVal</tt> that represents their multiplication (which in
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this case is a new symbolic expression, which we might call <tt>$1</tt>). When we
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evaluate the assignment to <tt>y</tt>, we again compute its lvalue (a <tt>MemRegion</tt>),
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and then bind the <tt>SVal</tt> for the RHS (which references the symbolic value <tt>$1</tt>)
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to the <tt>MemRegion</tt> in the symbolic store.
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<br>
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The second line is similar. When we evaluate <tt>x</tt> again, we do the same
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dance, and create an <tt>SVal</tt> that references the symbol <tt>$0</tt>. Note, two <tt>SVals</tt>
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might reference the same underlying values.
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<p>
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To summarize, MemRegions are unique names for blocks of memory. Symbols are
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unique names for abstract symbolic values. Some MemRegions represents abstract
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symbolic chunks of memory, and thus are also based on symbols. SVals are just
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references to values, and can reference either MemRegions, Symbols, or concrete
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values (e.g., the number 1).
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<!--
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TODO: Add a picture.
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<br>
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Symbols<br>
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FunctionalObjects are used throughout.
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-->
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<h2 id=idea>Idea for a Checker</h2>
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Here are several questions which you should consider when evaluating your
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checker idea:
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<ul>
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<li>Can the check be effectively implemented without path-sensitive
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analysis? See <a href="#ast">AST Visitors</a>.</li>
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<li>How high the false positive rate is going to be? Looking at the occurrences
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of the issue you want to write a checker for in the existing code bases might
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give you some ideas. </li>
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<li>How the current limitations of the analysis will effect the false alarm
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rate? Currently, the analyzer only reasons about one procedure at a time (no
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inter-procedural analysis). Also, it uses a simple range tracking based
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solver to model symbolic execution.</li>
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<li>Consult the <a
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href="http://llvm.org/bugs/buglist.cgi?query_format=advanced&bug_status=NEW&bug_status=REOPENED&version=trunk&component=Static%20Analyzer&product=clang">Bugzilla database</a>
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to get some ideas for new checkers and consider starting with improving/fixing
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bugs in the existing checkers.</li>
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</ul>
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<h2 id=registration>Checker Registration</h2>
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All checker implementation files are located in <tt>clang/lib/StaticAnalyzer/Checkers</tt>
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folder. Follow the steps below to register a new checker with the analyzer.
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<ol>
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<li>Create a new checker implementation file, for example <tt>./lib/StaticAnalyzer/Checkers/NewChecker.cpp</tt>
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<pre class="code_example">
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using namespace clang;
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using namespace ento;
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namespace {
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class NewChecker: public Checker< check::PreStmt<CallExpr> > {
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public:
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void checkPreStmt(const CallExpr *CE, CheckerContext &Ctx) const {}
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}
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}
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void ento::registerNewChecker(CheckerManager &mgr) {
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mgr.registerChecker<NewChecker>();
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}
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</pre>
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<li>Pick the package name for your checker and add the registration code to
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<tt>./lib/StaticAnalyzer/Checkers/Checkers.td</tt>. Note, all checkers should
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first be developed as experimental. Suppose our new checker performs security
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related checks, then we should add the following lines under
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<tt>SecurityExperimental</tt> package:
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<pre class="code_example">
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let ParentPackage = SecurityExperimental in {
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...
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def NewChecker : Checker<"NewChecker">,
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HelpText<"This text should give a short description of the checks performed.">,
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DescFile<"NewChecker.cpp">;
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...
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} // end "security.experimental"
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</pre>
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<li>Make the source code file visible to CMake by adding it to
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<tt>./lib/StaticAnalyzer/Checkers/CMakeLists.txt</tt>.
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<li>Compile and see your checker in the list of available checkers by running:<br>
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<tt><b>$clang -cc1 -analyzer-checker-help</b></tt>
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</ol>
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<h2 id=skeleton>Checker Skeleton</h2>
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There are two main decisions you need to make:
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<ul>
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<li> Which events the checker should be tracking.
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See <a href="http://clang.llvm.org/doxygen/classento_1_1CheckerDocumentation.html">CheckerDocumentation</a>
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for the list of available checker callbacks.</li>
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<li> What data you want to store as part of the checker-specific program
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state. Try to minimize the checker state as much as possible. </li>
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</ul>
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<h2 id=bugs>Bug Reports</h2>
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<h2 id=ast>AST Visitors</h2>
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Some checks might not require path-sensitivity to be effective. Simple AST walk
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might be sufficient. If that is the case, consider implementing a Clang
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compiler warning. On the other hand, a check might not be acceptable as a compiler
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warning; for example, because of a relatively high false positive rate. In this
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situation, AST callbacks <tt><b>checkASTDecl</b></tt> and
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<tt><b>checkASTCodeBody</b></tt> are your best friends.
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<h2 id=testing>Testing</h2>
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Every patch should be well tested with Clang regression tests. The checker tests
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live in <tt>clang/test/Analysis</tt> folder. To run all of the analyzer tests,
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execute the following from the <tt>clang</tt> build directory:
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<pre class="code">
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$ <b>TESTDIRS=Analysis make test</b>
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</pre>
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<h2 id=commands>Useful Commands/Debugging Hints</h2>
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<ul>
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<li>
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While investigating a checker-related issue, instruct the analyzer to only
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execute a single checker:
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<br><tt>
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$ <b>clang -cc1 -analyze -analyzer-checker=osx.KeychainAPI test.c</b>
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</tt>
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</li>
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<li>
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To dump AST:
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<br><tt>
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$ <b>clang -cc1 -ast-dump test.c</b>
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</tt>
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</li>
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<li>
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To view/dump CFG use <tt>debug.ViewCFG</tt> or <tt>debug.DumpCFG</tt> checkers:
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<br><tt>
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$ <b>clang -cc1 -analyze -analyzer-checker=debug.ViewCFG test.c</b>
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</tt>
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</li>
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<li>
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To see all available debug checkers:
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<br><tt>
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$ <b>clang -cc1 -analyzer-checker-help | grep "debug"</b>
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</tt>
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</li>
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<li>
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To see which function is failing while processing a large file use
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<tt>-analyzer-display-progress</tt> option.
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</li>
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<li>
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While debugging execute <tt>clang -cc1 -analyze -analyzer-checker=core</tt>
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instead of <tt>clang --analyze</tt>, as the later would call the compiler
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in a separate process.
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</li>
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<li>
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To view <tt>ExplodedGraph</tt> (the state graph explored by the analyzer) while
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debugging, goto a frame that has <tt>clang::ento::ExprEngine</tt> object and
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execute:
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<br><tt>
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(gdb) <b>p ViewGraph(0)</b>
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</tt>
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</li>
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<li>
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To see the <tt>ProgramState</tt> while debugging use the following command.
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<br><tt>
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(gdb) <b>p State->dump()</b>
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</tt>
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</li>
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<li>
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To see <tt>clang::Expr</tt> while debugging use the following command. If you
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pass in a SourceManager object, it will also dump the corresponding line in the
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source code.
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<br><tt>
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(gdb) <b>p E->dump()</b>
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</tt>
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</li>
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<li>
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To dump AST of a method that the current <tt>ExplodedNode</tt> belongs to:
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<br><tt>
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(gdb) <b>p C.getPredecessor()->getCodeDecl().getBody()->dump()</b>
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(gdb) <b>p C.getPredecessor()->getCodeDecl().getBody()->dump(getContext().getSourceManager())</b>
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</tt>
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</li>
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</ul>
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</div>
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</div>
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</body>
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</html>
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