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| <section id="nacl-and-pnacl"> |
| <span id="id1"></span><h1 id="nacl-and-pnacl"><span id="id1"></span>NaCl and PNaCl</h1> |
| <p>This document describes the differences between <strong>Native Client</strong> and |
| <strong>Portable Native Client</strong>, and provides recommendations for when to use each.</p> |
| <div class="contents local" id="contents" style="display: none"> |
| <ul class="small-gap"> |
| <li><a class="reference internal" href="#native-client-nacl" id="id3">Native Client (NaCl)</a></li> |
| <li><a class="reference internal" href="#portable-native-client-pnacl" id="id4">Portable Native Client (PNaCl)</a></li> |
| <li><a class="reference internal" href="#when-to-use-pnacl" id="id5">When to use PNaCl</a></li> |
| <li><a class="reference internal" href="#when-to-use-nacl" id="id6">When to use NaCl</a></li> |
| </ul> |
| |
| </div><section id="native-client-nacl"> |
| <h2 id="native-client-nacl">Native Client (NaCl)</h2> |
| <p>Native Client enables the execution of native code securely inside web |
| applications through the use of advanced <a class="reference external" href="/native-client/community/talks#research">Software Fault Isolation (SFI) |
| techniques</a>. Since its launch in |
| 2011, Native Client has provided developers with the ability to harness a |
| client machine’s computational power to a much fuller extent than traditional |
| web technologies, by running compiled C and C++ code at near-native speeds and |
| taking advantage of multiple cores with shared memory.</p> |
| <p>While Native Client provides operating system independence, it requires |
| developers to generate architecture-specific executable modules |
| (<strong>nexe</strong> modules) for each hardware platform. This is not only inconvenient |
| for developers, but architecture-specific machine code is not portable and thus |
| not well-suited for the open web. The traditional method of application |
| distribution on the web is through a self-contained bundle of HTML, CSS, |
| JavaScript, and other resources (images, etc.) that can be hosted on a server |
| and run inside a web browser. With this type of distribution, a website |
| created today should still work years later, on all platforms. |
| Architecture-specific executables are clearly not a good fit for distribution |
| on the web. As a consequence, Native Client has been restricted to |
| applications and browser extensions that are installed through the |
| Chrome Web Store.</p> |
| </section><section id="portable-native-client-pnacl"> |
| <h2 id="portable-native-client-pnacl">Portable Native Client (PNaCl)</h2> |
| <p>PNaCl solves the portability problem by splitting the compilation process |
| into two parts:</p> |
| <ol class="arabic simple"> |
| <li>compiling the source code to a portable bitcode format, and</li> |
| <li>translating the bitcode to a host-specific executable.</li> |
| </ol> |
| <p>PNaCl enables developers |
| to distribute <strong>portable executables</strong> (<strong>pexe</strong> modules) that the hosting |
| environment (e.g., the Chrome browser) can translate to native code before |
| executing. This portability aligns Native Client with existing open web |
| technologies such as JavaScript: A developer can distribute a <strong>pexe</strong> |
| as part of an application (along with HTML, CSS, and JavaScript), |
| and the user’s machine is simply able to run it.</p> |
| <p>With PNaCl, a developer generates a single <strong>pexe</strong> from source code, |
| rather than multiple platform-specific nexes. The <strong>pexe</strong> provides both |
| architecture- and OS-independence. Since the <strong>pexe</strong> uses an abstract, |
| architecture-independent format, it does not suffer from the portability |
| problem described above. Future versions of hosting environments should |
| have no problem executing the <strong>pexe</strong>, even on new architectures. |
| Moreover, if an existing architecture is subsequently enhanced, the |
| <strong>pexe</strong> doesn’t even have to be recompiled—in some cases the |
| client-side translation will automatically be able to take advantage of |
| the new capabilities.</p> |
| <p><strong>In short, PNaCl combines the portability of existing web technologies with |
| the performance and security benefits of Native Client.</strong></p> |
| <p>With the advent of PNaCl, the distribution restriction of Native Client |
| can be lifted. Specifically, a <strong>pexe</strong> module can be part of any web |
| application—it does not have to be distributed through the Chrome Web |
| Store.</p> |
| <p>PNaCl is a new technology, and as such it still has a few limitations |
| as compared to NaCl. These limitations are described below.</p> |
| </section><section id="when-to-use-pnacl"> |
| <h2 id="when-to-use-pnacl">When to use PNaCl</h2> |
| <p>PNaCl is the preferred toolchain for Native Client, and the only way to deploy |
| Native Client modules on the open web. Unless your project is subject to one |
| of the narrow limitations described below |
| (see <a class="reference internal" href="#when-to-use-nacl"><em>When to use NaCl</em></a>), you should use PNaCl.</p> |
| <p>Beginning with version 31, the Chrome browser supports translation of |
| <strong>pexe</strong> modules and their use in web applications, without requiring |
| any installation (either of a browser plugin or of the applications |
| themselves). Native Client and PNaCl are open-source technologies, and |
| our hope is that they will be added to other hosting platforms in the |
| future.</p> |
| <p>If controlled distribution through the Chrome Web Store is an important part |
| of your product plan, the benefits of PNaCl are less critical for you. But |
| you can still use the PNaCl toolchain and distribute your application |
| through the Chrome Web Store, and thereby take advantage of the |
| conveniences of PNaCl, such as not having to explicitly compile your application |
| for all supported architectures.</p> |
| </section><section id="when-to-use-nacl"> |
| <span id="id2"></span><h2 id="when-to-use-nacl"><span id="id2"></span>When to use NaCl</h2> |
| <p>The limitations below apply to the current release of PNaCl. If any of |
| these limitations are critical for your application, you should use |
| non-portable NaCl:</p> |
| <ul class="small-gap"> |
| <li>By its nature, PNaCl does not support architecture-specific |
| instructions in an application (i.e., inline assembly), but tries to |
| offer high-performance portable equivalents. One such example is |
| PNaCl’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> |
| <li>Currently PNaCl only supports static linking with the <code>newlib</code> |
| C standard library (the Native Client SDK provides a PNaCl port of |
| <code>newlib</code>). Dynamic linking and <code>glibc</code> are not yet supported. |
| Work is under way to enable dynamic linking in future versions of PNaCl.</li> |
| <li>In the initial release, PNaCl does not support some GNU extensions |
| like taking the address of a label for computed <code>goto</code>, or nested |
| functions.</li> |
| </ul> |
| </section></section> |
| |
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