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7 <title>Comparing clang to other open source compilers</title>
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14 <h1>Clang vs Other Open Source Compilers</h1>
16 <p>Building an entirely new compiler front-end is a big task, and it isn't
17 always clear to people why we decided to do this. Here we compare clang
18 and its goals to other open source compiler front-ends that are
19 available. We restrict the discussion to very specific objective points
20 to avoid controversy where possible. Also, software is infinitely
21 mutable, so we don't talk about little details that can be fixed with
22 a reasonable amount of effort: we'll talk about issues that are
23 difficult to fix for architectural or political reasons.</p>
25 <p>The goal of this list is to describe how differences in goals lead to
26 different strengths and weaknesses, not to make some compiler look bad.
27 This will hopefully help you to evaluate whether using clang is a good
28 idea for your personal goals. Because we don't know specifically what
29 <em>you</em> want to do, we describe the features of these compilers in
30 terms of <em>our</em> goals: if you are only interested in static
31 analysis, you may not care that something lacks codegen support, for
32 example.</p>
34 <p>Please email cfe-dev if you think we should add another compiler to this
35 list or if you think some characterization is unfair here.</p>
37 <ul>
38 <li><a href="#gcc">Clang vs GCC</a> (GNU Compiler Collection)</li>
39 <li><a href="#elsa">Clang vs Elsa</a> (Elkhound-based C++ Parser)</li>
40 <li><a href="#pcc">Clang vs PCC</a> (Portable C Compiler)</li>
41 </ul>
44 <!--=====================================================================-->
45 <h2><a name="gcc">Clang vs GCC (GNU Compiler Collection)</a></h2>
46 <!--=====================================================================-->
48 <p>Pro's of GCC vs clang:</p>
50 <ul>
51 <li>GCC supports languages that clang does not aim to, such as Java, Ada,
52 FORTRAN, etc.</li>
53 <li><a href="cxx_status.html">Clang support for C++</a> is more compliant
54 than GCC's in many ways, but is not as mature as GCC's. GCC has several
55 C++'0x features that Clang does not yet support (e.g. variadic
56 templates).</li>
57 <li>GCC supports more targets than LLVM.</li>
58 <li>GCC is popular and widely adopted.</li>
59 <li>GCC does not require a C++ compiler to build it.</li>
60 </ul>
62 <p>Pro's of clang vs GCC:</p>
64 <ul>
65 <li>The Clang ASTs and design are intended to be <a
66 href="features.html#simplecode">easily understandable</a> by
67 anyone who is familiar with the languages involved and who has a basic
68 understanding of how a compiler works. GCC has a very old codebase
69 which presents a steep learning curve to new developers.</li>
70 <li>Clang is designed as an API from its inception, allowing it to be reused
71 by source analysis tools, refactoring, IDEs (etc) as well as for code
72 generation. GCC is built as a monolithic static compiler, which makes
73 it extremely difficult to use as an API and integrate into other tools.
74 Further, its historic design and <a
75 href="http://gcc.gnu.org/ml/gcc/2007-11/msg00460.html">current</a>
76 <a href="http://gcc.gnu.org/ml/gcc/2004-12/msg00888.html">policy</a>
77 makes it difficult to decouple the front-end from the rest of the
78 compiler. </li>
79 <li>Various GCC design decisions make it very difficult to reuse: its build
80 system is difficult to modify, you can't link multiple targets into one
81 binary, you can't link multiple front-ends into one binary, it uses a
82 custom garbage collector, uses global variables extensively, is not
83 reentrant or multi-threadable, etc. Clang has none of these problems.
84 </li>
85 <li>For every token, clang tracks information about where it was written and
86 where it was ultimately expanded into if it was involved in a macro.
87 GCC does not track information about macro instantiations when parsing
88 source code. This makes it very difficult for source rewriting tools
89 (e.g. for refactoring) to work in the presence of (even simple)
90 macros.</li>
91 <li>Clang does not implicitly simplify code as it parses it like GCC does.
92 Doing so causes many problems for source analysis tools: as one simple
93 example, if you write "x-x" in your source code, the GCC AST will
94 contain "0", with no mention of 'x'. This is extremely bad for a
95 refactoring tool that wants to rename 'x'.</li>
96 <li>Clang can serialize its AST out to disk and read it back into another
97 program, which is useful for whole program analysis. GCC does not have
98 this. GCC's PCH mechanism (which is just a dump of the compiler
99 memory image) is related, but is architecturally only
100 able to read the dump back into the exact same executable as the one
101 that produced it (it is not a structured format).</li>
102 <li>Clang is <a href="features.html#performance">much faster and uses far
103 less memory</a> than GCC.</li>
104 <li>Clang aims to provide extremely clear and concise diagnostics (error and
105 warning messages), and includes support for <a
106 href="diagnostics.html">expressive diagnostics</a>. GCC's warnings are
107 sometimes acceptable, but are often confusing and it does not support
108 expressive diagnostics. Clang also preserves typedefs in diagnostics
109 consistently, showing macro expansions and many other features.</li>
110 <li>GCC is licensed under the GPL license. clang uses a BSD license, which
111 allows it to be used by projects that do not themselves want to be
112 GPL.</li>
113 <li>Clang inherits a number of features from its use of LLVM as a backend,
114 including support for a bytecode representation for intermediate code,
115 pluggable optimizers, link-time optimization support, Just-In-Time
116 compilation, ability to link in multiple code generators, etc.</li>
117 </ul>
119 <!--=====================================================================-->
120 <h2><a name="elsa">Clang vs Elsa (Elkhound-based C++ Parser)</a></h2>
121 <!--=====================================================================-->
123 <p>Pro's of Elsa vs clang:</p>
125 <ul>
126 <li>Elsa's parser and AST is designed to be easily extensible by adding
127 grammar rules. Clang has a very simple and easily hackable parser,
128 but requires you to write C++ code to do it.</li>
129 </ul>
131 <p>Pro's of clang vs Elsa:</p>
133 <ul>
134 <li>The Elsa community is extremely small and major development work seems
135 to have ceased in 2005. Work continued to be used by other small
136 projects (e.g. Oink), but Oink is apparently dead now too. Clang has a
137 vibrant community including developers that
138 are paid to work on it full time. In practice this means that you can
139 file bugs against Clang and they will often be fixed for you. If you
140 use Elsa, you are (mostly) on your own for bug fixes and feature
141 enhancements.</li>
142 <li>Elsa is not built as a stack of reusable libraries like clang is. It is
143 very difficult to use part of Elsa without the whole front-end. For
144 example, you cannot use Elsa to parse C/ObjC code without building an
145 AST. You can do this in Clang and it is much faster than building an
146 AST.</li>
147 <li>Elsa does not have an integrated preprocessor, which makes it extremely
148 difficult to accurately map from a source location in the AST back to
149 its original position before preprocessing. Like GCC, it does not keep
150 track of macro expansions.</li>
151 <li>Elsa is even slower and uses more memory than GCC, which itself requires
152 far more space and time than clang.</li>
153 <li>Elsa only does partial semantic analysis. It is intended to work on
154 code that is already validated by GCC, so it does not do many semantic
155 checks required by the languages it implements.</li>
156 <li>Elsa does not support Objective-C.</li>
157 <li>Elsa does not support native code generation.</li>
158 </ul>
160 <p>Note that there is a fork of Elsa known as "Pork". It addresses some of
161 these shortcomings by loosely integrating a preprocessor. This allows it
162 to map from a source location in the AST to the original position before
163 preprocessing, providing it better support for static analysis and
164 refactoring. Note that Pork is in stasis now too.</p>
167 <!--=====================================================================-->
168 <h2><a name="pcc">Clang vs PCC (Portable C Compiler)</a></h2>
169 <!--=====================================================================-->
171 <p>Pro's of PCC vs clang:</p>
173 <ul>
174 <li>The PCC source base is very small and builds quickly with just a C
175 compiler.</li>
176 </ul>
178 <p>Pro's of clang vs PCC:</p>
180 <ul>
181 <li>PCC dates from the 1970's and has been dormant for most of that time.
182 The clang + llvm communities are very active.</li>
183 <li>PCC doesn't support Objective-C or C++ and doesn't aim to support
184 C++.</li>
185 <li>PCC's code generation is very limited compared to LLVM. It produces very
186 inefficient code and does not support many important targets.</li>
187 <li>Like Elsa, PCC's does not have an integrated preprocessor, making it
188 extremely difficult to use it for source analysis tools.</li>
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