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3 <section id="nacl-and-pnacl">
4 <span id="id1"></span><h1 id="nacl-and-pnacl"><span id="id1"></span>NaCl and PNaCl</h1>
5 <p>This document describes the differences between <strong>Native Client</strong> and
6 <strong>Portable Native Client</strong>, and provides recommendations for when to use each.</p>
7 <div class="contents local" id="contents" style="display: none">
8 <ul class="small-gap">
9 <li><a class="reference internal" href="#native-client-nacl" id="id6">Native Client (NaCl)</a></li>
10 <li><a class="reference internal" href="#portable-native-client-pnacl" id="id7">Portable Native Client (PNaCl)</a></li>
11 <li><a class="reference internal" href="#when-to-use-pnacl" id="id8">When to use PNaCl</a></li>
12 <li><a class="reference internal" href="#when-to-use-nacl" id="id9">When to use NaCl</a></li>
13 </ul>
15 </div><h2 id="native-client-nacl"><span id="id2"></span>Native Client (NaCl)</h2>
16 <p>Native Client enables the execution of native code securely inside web
17 applications through the use of advanced <a class="reference external" href="http://research.google.com/pubs/pub35649.html">Software Fault Isolation (SFI)
18 techniques</a>. Native Client
19 allows you to harness a client machine&#8217;s computational power to a fuller extent
20 than traditional web technologies. It does this by running compiled C and C++
21 code at near-native speeds, and exposing a CPU&#8217;s full capabilities, including
22 SIMD vectors and multiple-core processing with shared memory.</p>
23 <p>While Native Client provides operating system independence, it requires you to
24 generate architecture-specific executables (<strong>nexe</strong>) for each hardware
25 platform. This is neither portable nor convenient, making it ill-suited for the
26 open web.</p>
27 <p>The traditional method of application distribution on the web is through self-
28 contained bundles of HTML, CSS, JavaScript, and other resources (images, etc.)
29 that can be hosted on a server and run inside a web browser. With this type of
30 distribution, a website created today should still work years later, on all
31 platforms. Architecture-specific executables are clearly not a good fit for
32 distribution on the web. Consequently, Native Client has been until recently
33 restricted to applications and browser extensions that are installed through the
34 Chrome Web Store.</p>
35 <h2 id="portable-native-client-pnacl"><span id="id3"></span>Portable Native Client (PNaCl)</h2>
36 <p>PNaCl solves the portability problem by splitting the compilation process
37 into two parts:</p>
38 <ol class="arabic simple">
39 <li>compiling the source code to a bitcode executable (pexe), and</li>
40 <li>translating the bitcode to a host-specific executable as soon as the module
41 loads in the browser but before any code execution.</li>
42 </ol>
43 <p>This portability aligns Native Client with existing open web technologies such
44 as JavaScript. You can distribute a pexe as part of an application (along with
45 HTML, CSS, and JavaScript), and the user&#8217;s machine is simply able to run it.</p>
46 <p>With PNaCl, you&#8217;ll generate a single pexe, rather than multiple platform-
47 specific nexes. Since the pexe uses an abstract, architecture- and OS-
48 independent format, it does not suffer from the portability problem described
49 above. Although, PNaCl can be more efficient on some operating systems than on
50 others. PNaCl boasts the same level of security as NaCl. Future versions of
51 hosting environments should have no problem executing the pexe, even on new
52 architectures. Moreover, if an existing architecture is enhanced, the pexe
53 doesn&#8217;t need to be recompiled. In some cases the client-side translation will
54 automatically take advantage of new capabilities. A pexe can be part of any web
55 application. It does not have to be distributed through the Chrome Web Store. In
56 short, PNaCl combines the portability of existing web technologies with the
57 performance and security benefits of Native Client.</p>
58 <p>PNaCl is a new technology, and as such it still has a few limitations
59 as compared to NaCl. These limitations are described below.</p>
60 <h2 id="when-to-use-pnacl"><span id="id4"></span>When to use PNaCl</h2>
61 <p>PNaCl is the preferred toolchain for Native Client, and the only way to deploy
62 Native Client modules without the Google Web Store. Unless your project is
63 subject to one of the narrow limitations described under &#8220;<a class="reference internal" href="#when-to-use-nacl"><em>When to use
64 NaCl</em></a>&#8221;, you should use PNaCl.</p>
65 <p>Chrome supports translation of pexe modules and their use in web applications
66 without requiring installation either of a browser plug-in or of the
67 applications themselves. Native Client and PNaCl are open-source technologies,
68 and our hope is that they will be added to other hosting platforms in the
69 future.</p>
70 <p>If controlled distribution through the Chrome Web Store is an important part of
71 your product plan, the benefits of PNaCl are less critical for you. But you can
72 still use the PNaCl toolchain and distribute your application through the Chrome
73 Web Store, and thereby take advantage of the conveniences of PNaCl, such as not
74 having to explicitly compile your application for all supported architectures.</p>
75 <h2 id="when-to-use-nacl"><span id="id5"></span>When to use NaCl</h2>
76 <p>Use NaCl if any of the following apply to your application:</p>
77 <ul class="small-gap">
78 <li>Your application requires architecture-specific instructions such as, for
79 example, inline assembly. PNaCl tries to offer high-performance portable
80 equivalents. One such example is PNaCl&#8217;s <a class="reference internal" href="/native-client/reference/pnacl-c-cpp-language-support.html#portable-simd-vectors"><em>Portable SIMD Vectors</em></a>.</li>
81 <li>Your application uses dynamic linking. PNaCl only supports static linking
82 with a PNaCl port of the <code>newlib</code> C standard library. Dynamic linking and
83 <code>glibc</code> are not yet supported in PNaCl. Work is under way to enable dynamic
84 linking in future versions of PNaCl.</li>
85 <li>Your application uses certain GNU extensions not supported by PNaCl&#8217;s LLVM
86 toolchain, like taking the address of a label for computed <code>goto</code>, or nested
87 functions.</li>
88 </ul>
89 </section>
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