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| <!--=======================================================================--> |
| <h1>Expressive Diagnostics</h1> |
| <!--=======================================================================--> |
| |
| <p>In addition to being fast and functional, we aim to make Clang extremely user |
| friendly. As far as a command-line compiler goes, this basically boils down to |
| making the diagnostics (error and warning messages) generated by the compiler |
| be as useful as possible. There are several ways that we do this. This section |
| talks about the experience provided by the command line compiler, contrasting |
| Clang output to GCC 4.9's output in some cases. |
| </p> |
| |
| <h2>Column Numbers and Caret Diagnostics</h2> |
| |
| <p>First, all diagnostics produced by clang include full column number |
| information. The clang command-line compiler driver uses this information |
| to print "point diagnostics". |
| (IDEs can use the information to display in-line error markup.) |
| This is nice because it makes it very easy to understand exactly |
| what is wrong in a particular piece of code.</p> |
| |
| <p>The point (the green "^" character) exactly shows where the problem is, even |
| inside of a string. This makes it really easy to jump to the problem and |
| helps when multiple instances of the same character occur on a line. (We'll |
| revisit this more in following examples.)</p> |
| |
| <pre> |
| $ <span class="cmd">gcc-4.9 -fsyntax-only -Wformat format-strings.c</span> |
| format-strings.c: In function 'void f()': |
| format-strings.c:91:16: warning: field precision specifier '.*' expects a matching 'int' argument [-Wformat=] |
| printf("%.*d"); |
| ^ |
| format-strings.c:91:16: warning: format '%d' expects a matching 'int' argument [-Wformat=] |
| $ <span class="cmd">clang -fsyntax-only format-strings.c</span> |
| <span class="loc">format-strings.c:91:13:</span> <span class="warn">warning:</span> <span class="msg">'.*' specified field precision is missing a matching 'int' argument</span> |
| <span class="snip" > printf("%.*d");</span> |
| <span class="point"> ^</span> |
| </pre> |
| |
| <p>Note that modern versions of GCC have followed Clang's lead, and are |
| now able to give a column for a diagnostic, and include a snippet of source |
| text in the result. However, Clang's column number is much more accurate, |
| pointing at the problematic format specifier, rather than the <tt>)</tt> |
| character the parser had reached when the problem was detected. |
| Also, Clang's diagnostic is colored by default, making it easier to |
| distinguish from nearby text.</p> |
| |
| <h2>Range Highlighting for Related Text</h2> |
| |
| <p>Clang captures and accurately tracks range information for expressions, |
| statements, and other constructs in your program and uses this to make |
| diagnostics highlight related information. In the following somewhat |
| nonsensical example you can see that you don't even need to see the original source code to |
| understand what is wrong based on the Clang error. Because clang prints a |
| point, you know exactly <em>which</em> plus it is complaining about. The range |
| information highlights the left and right side of the plus which makes it |
| immediately obvious what the compiler is talking about. |
| Range information is very useful for |
| cases involving precedence issues and many other cases.</p> |
| |
| <pre> |
| $ <span class="cmd">gcc-4.9 -fsyntax-only t.c</span> |
| t.c: In function 'int f(int, int)': |
| t.c:7:39: error: invalid operands to binary + (have 'int' and 'struct A') |
| return y + func(y ? ((SomeA.X + 40) + SomeA) / 42 + SomeA.X : SomeA.X); |
| ^ |
| $ <span class="cmd">clang -fsyntax-only t.c</span> |
| <span class="loc">t.c:7:39:</span> <span class="err">error:</span> <span class="msg">invalid operands to binary expression ('int' and 'struct A')</span> |
| <span class="snip" > return y + func(y ? ((SomeA.X + 40) + SomeA) / 42 + SomeA.X : SomeA.X);</span> |
| <span class="point"> ~~~~~~~~~~~~~~ ^ ~~~~~</span> |
| </pre> |
| |
| <h2>Precision in Wording</h2> |
| |
| <p>A detail is that we have tried really hard to make the diagnostics that come |
| out of clang contain exactly the pertinent information about what is wrong and |
| why. In the example above, we tell you what the inferred types are for |
| the left and right hand sides, and we don't repeat what is obvious from the |
| point (e.g., that this is a "binary +").</p> |
| |
| <p>Many other examples abound. In the following example, not only do we tell you |
| that there is a problem with the <tt>*</tt> |
| and point to it, we say exactly why and tell you what the type is (in case it is |
| a complicated subexpression, such as a call to an overloaded function). This |
| sort of attention to detail makes it much easier to understand and fix problems |
| quickly.</p> |
| |
| <pre> |
| $ <span class="cmd">gcc-4.9 -fsyntax-only t.c</span> |
| t.c:5:11: error: invalid type argument of unary '*' (have 'int') |
| return *SomeA.X; |
| ^ |
| $ <span class="cmd">clang -fsyntax-only t.c</span> |
| <span class="loc">t.c:5:11:</span> <span class="err">error:</span> <span class="msg">indirection requires pointer operand ('int' invalid)</span> |
| <span class="snip" > int y = *SomeA.X;</span> |
| <span class="point"> ^~~~~~~~</span> |
| </pre> |
| |
| <h2>Typedef Preservation and Selective Unwrapping</h2> |
| |
| <p>Many programmers use high-level user defined types, typedefs, and other |
| syntactic sugar to refer to types in their program. This is useful because they |
| can abbreviate otherwise very long types and it is useful to preserve the |
| typename in diagnostics. However, sometimes very simple typedefs can wrap |
| trivial types and it is important to strip off the typedef to understand what |
| is going on. Clang aims to handle both cases well.<p> |
| |
| <p>The following example shows where it is important to preserve |
| a typedef in C.</p> |
| |
| <pre> |
| $ <span class="cmd">clang -fsyntax-only t.c</span> |
| <span class="loc">t.c:15:11:</span> <span class="err">error:</span> <span class="msg">can't convert between vector values of different size ('__m128' and 'int const *')</span> |
| <span class="snip"> myvec[1]/P;</span> |
| <span class="point"> ~~~~~~~~^~</span> |
| </pre> |
| |
| <p>The following example shows where it is useful for the compiler to expose |
| underlying details of a typedef. If the user was somehow confused about how the |
| system "pid_t" typedef is defined, Clang helpfully displays it with "aka".</p> |
| |
| <pre> |
| $ <span class="cmd">clang -fsyntax-only t.c</span> |
| <span class="loc">t.c:13:9:</span> <span class="err">error:</span> <span class="msg">member reference base type 'pid_t' (aka 'int') is not a structure or union</span> |
| <span class="snip"> myvar = myvar.x;</span> |
| <span class="point"> ~~~~~ ^</span> |
| </pre> |
| |
| <p>In C++, type preservation includes retaining any qualification written into type names. For example, if we take a small snippet of code such as: |
| |
| <blockquote> |
| <pre> |
| namespace services { |
| struct WebService { }; |
| } |
| namespace myapp { |
| namespace servers { |
| struct Server { }; |
| } |
| } |
| |
| using namespace myapp; |
| void addHTTPService(servers::Server const &server, ::services::WebService const *http) { |
| server += http; |
| } |
| </pre> |
| </blockquote> |
| |
| <p>and then compile it, we see that Clang is both providing accurate information and is retaining the types as written by the user (e.g., "servers::Server", "::services::WebService"): |
| |
| <pre> |
| $ <span class="cmd">clang -fsyntax-only t.cpp</span> |
| <span class="loc">t.cpp:9:10:</span> <span class="err">error:</span> <span class="msg">invalid operands to binary expression ('servers::Server const' and '::services::WebService const *')</span> |
| <span class="snip">server += http;</span> |
| <span class="point">~~~~~~ ^ ~~~~</span> |
| </pre> |
| |
| <p>Naturally, type preservation extends to uses of templates, and Clang retains information about how a particular template specialization (like <code>std::vector<Real></code>) was spelled within the source code. For example:</p> |
| |
| <pre> |
| $ <span class="cmd">clang -fsyntax-only t.cpp</span> |
| <span class="loc">t.cpp:12:7:</span> <span class="err">error:</span> <span class="msg">incompatible type assigning 'vector<Real>', expected 'std::string' (aka 'class std::basic_string<char>')</span> |
| <span class="snip">str = vec</span>; |
| <span class="point">^ ~~~</span> |
| </pre> |
| |
| <h2>Fix-it Hints</h2> |
| |
| <p>"Fix-it" hints provide advice for fixing small, localized problems |
| in source code. When Clang produces a diagnostic about a particular |
| problem that it can work around (e.g., non-standard or redundant |
| syntax, missing keywords, common mistakes, etc.), it may also provide |
| specific guidance in the form of a code transformation to correct the |
| problem. In the following example, Clang warns about the use of a GCC |
| extension that has been considered obsolete since 1993. The underlined |
| code should be removed, then replaced with the code below the |
| point line (".x =" or ".y =", respectively).</p> |
| |
| <pre> |
| $ <span class="cmd">clang t.c</span> |
| <span class="loc">t.c:5:28:</span> <span class="warn">warning:</span> <span class="msg">use of GNU old-style field designator extension</span> |
| <span class="snip">struct point origin = { x: 0.0, y: 0.0 };</span> |
| <span class="err">~~</span> <span class="msg"><span class="point">^</span></span> |
| <span class="snip">.x = </span> |
| <span class="loc">t.c:5:36:</span> <span class="warn">warning:</span> <span class="msg">use of GNU old-style field designator extension</span> |
| <span class="snip">struct point origin = { x: 0.0, y: 0.0 };</span> |
| <span class="err">~~</span> <span class="msg"><span class="point">^</span></span> |
| <span class="snip">.y = </span> |
| </pre> |
| |
| <p>"Fix-it" hints are most useful for |
| working around common user errors and misconceptions. For example, C++ users |
| commonly forget the syntax for explicit specialization of class templates, |
| as in the error in the following example. Again, after describing the problem, |
| Clang provides the fix--add <code>template<></code>--as part of the |
| diagnostic.<p> |
| |
| <pre> |
| $ <span class="cmd">clang t.cpp</span> |
| <span class="loc">t.cpp:9:3:</span> <span class="err">error:</span> <span class="msg">template specialization requires 'template<>'</span> |
| struct iterator_traits<file_iterator> { |
| <span class="point">^</span> |
| <span class="snip">template<> </span> |
| </pre> |
| |
| <h2>Template Type Diffing</h2> |
| |
| <p>Templates types can be long and difficult to read. Moreso when part of an |
| error message. Instead of just printing out the type name, Clang has enough |
| information to remove the common elements and highlight the differences. To |
| show the template structure more clearly, the templated type can also be |
| printed as an indented text tree.</p> |
| |
| Default: template diff with type elision |
| <pre> |
| <span class="loc">t.cc:4:5:</span> <span class="note">note:</span> candidate function not viable: no known conversion from 'vector<map<[...], <span class="template-highlight">float</span>>>' to 'vector<map<[...], <span class="template-highlight">double</span>>>' for 1st argument; |
| </pre> |
| -fno-elide-type: template diff without elision |
| <pre> |
| <span class="loc">t.cc:4:5:</span> <span class="note">note:</span> candidate function not viable: no known conversion from 'vector<map<int, <span class="template-highlight">float</span>>>' to 'vector<map<int, <span class="template-highlight">double</span>>>' for 1st argument; |
| </pre> |
| -fdiagnostics-show-template-tree: template tree printing with elision |
| <pre> |
| <span class="loc">t.cc:4:5:</span> <span class="note">note:</span> candidate function not viable: no known conversion for 1st argument; |
| vector< |
| map< |
| [...], |
| [<span class="template-highlight">float</span> != <span class="template-highlight">double</span>]>> |
| </pre> |
| -fdiagnostics-show-template-tree -fno-elide-type: template tree printing with no elision |
| <pre> |
| <span class="loc">t.cc:4:5:</span> <span class="note">note:</span> candidate function not viable: no known conversion for 1st argument; |
| vector< |
| map< |
| int, |
| [<span class="template-highlight">float</span> != <span class="template-highlight">double</span>]>> |
| </pre> |
| |
| <h2>Automatic Macro Expansion</h2> |
| |
| <p>Many errors happen in macros that are sometimes deeply nested. With |
| traditional compilers, you need to dig deep into the definition of the macro to |
| understand how you got into trouble. The following simple example shows how |
| Clang helps you out by automatically printing instantiation information and |
| nested range information for diagnostics as they are instantiated through macros |
| and also shows how some of the other pieces work in a bigger example.</p> |
| |
| <pre> |
| $ <span class="cmd">clang -fsyntax-only t.c</span> |
| <span class="loc">t.c:80:3:</span> <span class="err">error:</span> <span class="msg">invalid operands to binary expression ('typeof(P)' (aka 'struct mystruct') and 'typeof(F)' (aka 'float'))</span> |
| <span class="snip"> X = MYMAX(P, F);</span> |
| <span class="point"> ^~~~~~~~~~~</span> |
| <span class="loc">t.c:76:94:</span> <span class="note">note:</span> expanded from: |
| <span class="snip">#define MYMAX(A,B) __extension__ ({ __typeof__(A) __a = (A); __typeof__(B) __b = (B); __a < __b ? __b : __a; })</span> |
| <span class="point"> ~~~ ^ ~~~</span> |
| </pre> |
| |
| <p>Here's another real world warning that occurs in the "window" Unix package (which |
| implements the "wwopen" class of APIs):</p> |
| |
| <pre> |
| $ <span class="cmd">clang -fsyntax-only t.c</span> |
| <span class="loc">t.c:22:2:</span> <span class="warn">warning:</span> <span class="msg">type specifier missing, defaults to 'int'</span> |
| <span class="snip"> ILPAD();</span> |
| <span class="point"> ^</span> |
| <span class="loc">t.c:17:17:</span> <span class="note">note:</span> expanded from: |
| <span class="snip">#define ILPAD() PAD((NROW - tt.tt_row) * 10) /* 1 ms per char */</span> |
| <span class="point"> ^</span> |
| <span class="loc">t.c:14:2:</span> <span class="note">note:</span> expanded from: |
| <span class="snip"> register i; \</span> |
| <span class="point"> ^</span> |
| </pre> |
| |
| <p>In practice, we've found that Clang's treatment of macros is actually more useful in multiply nested |
| macros that in simple ones.</p> |
| |
| <h2>Quality of Implementation and Attention to Detail</h2> |
| |
| <p>Finally, we have put a lot of work polishing the little things, because |
| little things add up over time and contribute to a great user experience.</p> |
| |
| <p>The following example shows that we recover from the simple case of |
| forgetting a ; after a struct definition much better than GCC.</p> |
| |
| <pre> |
| $ <span class="cmd">cat t.cc</span> |
| template<class T> |
| class a {}; |
| struct b {} |
| a<int> c; |
| $ <span class="cmd">gcc-4.9 t.cc</span> |
| t.cc:4:8: error: invalid declarator before 'c' |
| a<int> c; |
| ^ |
| $ <span class="cmd">clang t.cc</span> |
| <span class="loc">t.cc:3:12:</span> <span class="err">error:</span> <span class="msg">expected ';' after struct</span> |
| <span class="snip" >struct b {}</span> |
| <span class="point"> ^</span> |
| <span class="point"> ;</span> |
| </pre> |
| |
| <p>The following example shows that we diagnose and recover from a missing |
| <tt>typename</tt> keyword well, even in complex circumstances where GCC |
| cannot cope.</p> |
| |
| <pre> |
| $ <span class="cmd">cat t.cc</span> |
| template<class T> void f(T::type) { } |
| struct A { }; |
| void g() |
| { |
| A a; |
| f<A>(a); |
| } |
| $ <span class="cmd">gcc-4.9 t.cc</span> |
| t.cc:1:33: error: variable or field 'f' declared void |
| template<class T> void f(T::type) { } |
| ^ |
| t.cc: In function 'void g()': |
| t.cc:6:5: error: 'f' was not declared in this scope |
| f<A>(a); |
| ^ |
| t.cc:6:8: error: expected primary-expression before '>' token |
| f<A>(a); |
| ^ |
| $ <span class="cmd">clang t.cc</span> |
| <span class="loc">t.cc:1:26:</span> <span class="err">error:</span> <span class="msg">missing 'typename' prior to dependent type name 'T::type'</span> |
| <span class="snip" >template<class T> void f(T::type) { }</span> |
| <span class="point"> ^~~~~~~</span> |
| <span class="point"> typename </span> |
| <span class="loc">t.cc:6:5:</span> <span class="err">error:</span> <span class="msg">no matching function for call to 'f'</span> |
| <span class="snip" > f<A>(a);</span> |
| <span class="point"> ^~~~</span> |
| <span class="loc">t.cc:1:24:</span> <span class="note">note:</span> <span class="msg">candidate template ignored: substitution failure [with T = A]: no type named 'type' in 'A'</span> |
| <span class="snip" >template<class T> void f(T::type) { }</span> |
| <span class="point"> ^ ~~~~</span> |
| </pre> |
| |
| |
| |
| <p>While each of these details is minor, we feel that they all add up to provide |
| a much more polished experience.</p> |
| |
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