docs/html-ndk/ndk/guides/cpu-arm-neon.jd - platform/frameworks/base - Gitiles

 page.title=NEON Support
 @jd:body

 <div id="qv-wrapper">
     <div id="qv">
       <h2>On this page</h2>

       <ol>
         <li><a href="#ul">Using {@code LOCAL_ARM_NEON}</a></li>
         <li><a href="#uns">Using the {@code .neon} Suffix</a></li>
         <li><a href="#build">Build Requirements</a></li>
         <li><a href="#rd">Runtime Detection</a></li>
         <li><a href="#sc">Sample Code</a></li>
       </ol>
     </div>
   </div>

 <p>The NDK supports the ARM Advanced SIMD, an optional instruction-set extension of the ARMv7 spec.
 NEON provides a set of scalar/vector instructions and registers (shared with the FPU) comparable to
 MMX/SSE/3DNow! in the x86 world. To function, it requires VFPv3-D32 (32 hardware FPU 64-bit
 registers, instead of the minimum of 16).</p>

 <p>The NDK supports the compilation of modules or even specific source files with support for NEON.
 As a result, a specific compiler flag enables the use of GCC ARM NEON intrinsics and VFPv3-D32
 at the same time.</p>

 <p>Not all ARMv7-based Android devices support NEON, but devices that do may benefit significantly
 from its support for scalar/vector instructions. For x86 devices, the NDK can also translate NEON
 instructions into SSE, although with several restrictions. For more information, see
 <a href="{docRoot}ndk/guides/x86.html#an>x86 Support for ARM NEON Intrinsics.</a></p>

 <h2 id="ul">Using LOCAL_ARM_NEON</h2>
 <p>To have the NDK build all its source files with NEON support, include the following line in
 your module definition:</p>

 <pre class="no-pretty-print">
 LOCAL_ARM_NEON := true
 </pre>

 <p>It can be especially useful to build all source files with NEON support if you want to build a
 static or shared library that specifically contains NEON code paths.</p>

 <h2 id="uns">Using the .neon Suffix</h2>
 <p>When listing source files for your {@code LOCAL_SRC_FILES} variable, you have the option of
 using the {@code .neon} suffix to indicate that you want to build binaries with NEON support.
 For example, the following example builds one file with {@code .neon} support, and another
 without it:</p>

 <pre class="no-pretty-print">
 LOCAL_SRC_FILES := foo.c.neon bar.c
 </pre>

 <p>You can combine the {@code .neon} suffix with the {@code .arm} suffix, which specifies the 32-bit
 ARM instruction set for non-NEON instructions. In such a definition, {@code arm} must come before
 {@code neon}. For example: {@code foo.c.arm.neon} works, but {@code foo.c.neon.arm} does not.</p>

 <h2 id="build">Build Requirements</h2>
 <p>NEON support only works with the {@code armeabi-v7a} and {@code x86} ABIs. If the NDK build
 scripts encounter other ABIs while attempting to build with NEON support, the NDK build scripts
 exit. x86 provides <a href="x86.html">partial NEON support</a> via translation header. It is
 important to use checks like the following in your <a href="{docRoot}ndk/guides/android_mk.html">
 {@code Android.mk}</a> file:</p>

 <pre class="no-pretty-print">
 # define a static library containing our NEON code
 ifeq ($(TARGET_ARCH_ABI),$(filter $(TARGET_ARCH_ABI), armeabi-v7a x86))
 include $(CLEAR_VARS)
 LOCAL_MODULE    := mylib-neon
 LOCAL_SRC_FILES := mylib-neon.c
 LOCAL_ARM_NEON  := true
 include $(BUILD_STATIC_LIBRARY)
 endif # TARGET_ARCH_ABI == armeabi-v7a || x86
 </pre>

 <h2 id="rd">Runtime Detection</h2>
 <p>Your app must perform runtime detection to confirm that NEON-capable machine code can be run on
 the target device. This is because not all ARMv7-based Android devices support NEON. The app can
 perform this check using the
 <a href="{@docRoot}ndk/guides/cpu_features.html">{@code cpufeatures}</a> library that comes with
 this NDK.</p>

 <p>You should explicitly check that {@code android_getCpuFamily()} returns {@code
 ANDROID_CPU_FAMILY_ARM}, and that {@code android_getCpuFeatures()} returns a value including the
 {@code ANDROID_CPU_ARM_FEATURE_NEON flag} set. For example: </p>

 <pre class="no-pretty-print">
 #include &lt;cpu-features.h&gt;
 ...
 ...
 if (android_getCpuFamily() == ANDROID_CPU_FAMILY_ARM &amp;&amp;
     (android_getCpuFeatures() &amp; ANDROID_CPU_ARM_FEATURE_NEON) != 0)
 {
     // use NEON-optimized routines
     ...
 }
 else
 {
     // use non-NEON fallback routines instead
     ...
 }

 ...
 </pre>

 <h2 id="sc">Sample Code</h2>
 <p>The source code for the NDK's hello-neon sample provides an example of how to use the
 {@code cpufeatures} library and NEON intrinsics at the same time. This sample implements a tiny
 benchmark for a FIR filter loop using a C version, and a NEON-optimized one for devices that
 support it.</p>
	page.title=NEON Support
	@jd:body

	<div id="qv-wrapper">
	<div id="qv">
	<h2>On this page</h2>

	<ol>
	<li><a href="#ul">Using {@code LOCAL_ARM_NEON}</a></li>
	<li><a href="#uns">Using the {@code .neon} Suffix</a></li>
	<li><a href="#build">Build Requirements</a></li>
	<li><a href="#rd">Runtime Detection</a></li>
	<li><a href="#sc">Sample Code</a></li>
	</ol>
	</div>
	</div>

	<p>The NDK supports the ARM Advanced SIMD, an optional instruction-set extension of the ARMv7 spec.
	NEON provides a set of scalar/vector instructions and registers (shared with the FPU) comparable to
	MMX/SSE/3DNow! in the x86 world. To function, it requires VFPv3-D32 (32 hardware FPU 64-bit
	registers, instead of the minimum of 16).</p>

	<p>The NDK supports the compilation of modules or even specific source files with support for NEON.
	As a result, a specific compiler flag enables the use of GCC ARM NEON intrinsics and VFPv3-D32
	at the same time.</p>

	<p>Not all ARMv7-based Android devices support NEON, but devices that do may benefit significantly
	from its support for scalar/vector instructions. For x86 devices, the NDK can also translate NEON
	instructions into SSE, although with several restrictions. For more information, see
	<a href="{docRoot}ndk/guides/x86.html#an>x86 Support for ARM NEON Intrinsics.</a></p>

	<h2 id="ul">Using LOCAL_ARM_NEON</h2>
	<p>To have the NDK build all its source files with NEON support, include the following line in
	your module definition:</p>

	<pre class="no-pretty-print">
	LOCAL_ARM_NEON := true
	</pre>

	<p>It can be especially useful to build all source files with NEON support if you want to build a
	static or shared library that specifically contains NEON code paths.</p>

	<h2 id="uns">Using the .neon Suffix</h2>
	<p>When listing source files for your {@code LOCAL_SRC_FILES} variable, you have the option of
	using the {@code .neon} suffix to indicate that you want to build binaries with NEON support.
	For example, the following example builds one file with {@code .neon} support, and another
	without it:</p>

	<pre class="no-pretty-print">
	LOCAL_SRC_FILES := foo.c.neon bar.c
	</pre>

	<p>You can combine the {@code .neon} suffix with the {@code .arm} suffix, which specifies the 32-bit
	ARM instruction set for non-NEON instructions. In such a definition, {@code arm} must come before
	{@code neon}. For example: {@code foo.c.arm.neon} works, but {@code foo.c.neon.arm} does not.</p>

	<h2 id="build">Build Requirements</h2>
	<p>NEON support only works with the {@code armeabi-v7a} and {@code x86} ABIs. If the NDK build
	scripts encounter other ABIs while attempting to build with NEON support, the NDK build scripts
	exit. x86 provides <a href="x86.html">partial NEON support</a> via translation header. It is
	important to use checks like the following in your <a href="{docRoot}ndk/guides/android_mk.html">
	{@code Android.mk}</a> file:</p>

	<pre class="no-pretty-print">
	# define a static library containing our NEON code
	ifeq ($(TARGET_ARCH_ABI),$(filter $(TARGET_ARCH_ABI), armeabi-v7a x86))
	include $(CLEAR_VARS)
	LOCAL_MODULE := mylib-neon
	LOCAL_SRC_FILES := mylib-neon.c
	LOCAL_ARM_NEON := true
	include $(BUILD_STATIC_LIBRARY)
	endif # TARGET_ARCH_ABI == armeabi-v7a \|\| x86
	</pre>

	<h2 id="rd">Runtime Detection</h2>
	<p>Your app must perform runtime detection to confirm that NEON-capable machine code can be run on
	the target device. This is because not all ARMv7-based Android devices support NEON. The app can
	perform this check using the
	<a href="{@docRoot}ndk/guides/cpu_features.html">{@code cpufeatures}</a> library that comes with
	this NDK.</p>

	<p>You should explicitly check that {@code android_getCpuFamily()} returns {@code
	ANDROID_CPU_FAMILY_ARM}, and that {@code android_getCpuFeatures()} returns a value including the
	{@code ANDROID_CPU_ARM_FEATURE_NEON flag} set. For example: </p>

	<pre class="no-pretty-print">
	#include <cpu-features.h>
	...
	...
	if (android_getCpuFamily() == ANDROID_CPU_FAMILY_ARM &&
	(android_getCpuFeatures() & ANDROID_CPU_ARM_FEATURE_NEON) != 0)
	{
	// use NEON-optimized routines
	...
	}
	else
	{
	// use non-NEON fallback routines instead
	...
	}

	...
	</pre>

	<h2 id="sc">Sample Code</h2>
	<p>The source code for the NDK's hello-neon sample provides an example of how to use the
	{@code cpufeatures} library and NEON intrinsics at the same time. This sample implements a tiny
	benchmark for a FIR filter loop using a C version, and a NEON-optimized one for devices that
	support it.</p>