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英特尔集成性能原件 Windows 版 (产品编号：10921)

可构建随选即用的功能并提高应用程序性能。

标签：

开发商： Intel Software

当前版本：

产品类型：控件

产品功能：测试分析

平台语言：其他|.NET|JAVA|C++/ MFC

开源水平：不提供源码

本产品的分类与介绍仅供参考，具体以商家网站介绍为准，如有疑问请来电 023-68661681 咨询。

使用“英特尔集成性能原件（英特尔 IPP）Windows 版”，可构建随选即用的功能并提高应用程序性能。它利用跨多个平台的函数库，这些函数库中的函数均针对英特尔酷睿双核处理器的多核心功能进行过优化。您还可以使用各种预先构建的函数与编解码器，涉及领域包括：音频、视频及图像处理；密码技术；语音识别；以及矩阵、矢量数学及信号处理。

* 关于本产品的分类与介绍仅供参考，精准产品资料以官网介绍为准，如需购买请先行测试。

功能
多核处理器支持

图 1. 多核处理器使得多线程软件应用真正实现了并行执行
“英特尔® 集成性能原件”（英特尔® IPP）5.1 全面支持当今的各种多核心计算平台：

多核心优化函数：“矢量与统计”数学、“信号过滤”、“傅立叶变换”、“图像/JPEG 压缩与颜色转换”等领域的许多关键函数的内部都使用 OpenMP* 进行过多线程处理，可以在多核心系统上实现最佳性能。
多核心优化代码示例：许多“英特尔 IPP”代码示例都进行过多线程处理，以说明在视频编码与解码等应用程序中如何有效地使用“英特尔 IPP”函数。
真正线程安全的函数：所有的“英特尔 IPP”函数都完全能够确保线程安全，简化了集成到多线程应用程序中的工作。

如需有关线程技术与“英特尔 IPP”函数的详细信息，请参阅线程技术的常见问题 (FAQ) 页面。

性能优化的函数

“英特尔 IPP 5.1”中添加了一些新的优化技术，可以在最新的处理器（如英特尔® 酷睿™ 双核处理器与英特尔® 奔腾® D 处理器）上实现最佳性能。

使用众多技术领域中最为广泛的经过高度优化的函数，消除应用程序中可能出现的任何性能瓶颈：
视频编码：DV、MPEG-2、MPEG-4、H.263 以及 MPEG-4 Part 10 (H.264) 编解码器的关键算法组件。“图 2”显示 H.264 编解码器流程中适合使用“英特尔 IPP”视频编码组件（用蓝色方框表示）的地方。这些函数包括：
- 运动补偿
- 运动估计
- 改进的离散余弦变换
- 量化与反量化
- 熵编码

“视频”与“音频”代码示例演示如何使用“英特尔 IPP”函数实现编解码器。

图像处理：包含许多内置的图像处理函数，其中有：
计算机视觉：提供视频数据处理功能，包括：
颜色转换：采用以下技术改善图像颜色与颜色效果之间的转换效率：
字符串处理：使用“字符串处理”（查找、插入、删除、比较）与“常规表达式”，将文本数据库管理、搜索与检索或文档索引处理功能集成到应用程序中。
备注：“英特尔® PCA 处理器”上不提供。
JPEG 编码：JPEG、JPEG 2000 以及“动态 JPEG”编解码器的关键算法组件。“图 3”显示 JPEG 与 JPEG 2000 编解码器流程中适合使用“英特尔 IPP”的 JPEG 编码组件（用蓝色方框表示）的地方。
备注：“英特尔® PCA 处理器”上不提供。
语音编码：包含针对以下用途的函数：

它还包含用于“回声消除”与“通用语音类别”的语音函数。
信号处理：包含针对以下用途的信号处理功能：

备注：“英特尔® PCA 处理器”上不提供。
数据压缩：采用以下技术最大程度地压缩多媒体数据：
音频编码：MP3、AAC 以及 AC3 编解码器的关键算法组件。“图 4”显示 AAC 编解码器流程中适合使用“英特尔 IPP”的 JPEG 编码组件（用蓝色方框表示）的地方。这些函数包括：
- 哈夫曼编码
- 光谱数据预量化
- 改进的离散余弦变换
- 区块过滤
- 频域预测
- 光谱带复制
- 快速傅立叶变换
语音识别：通过采用以下技术，使应用程序支持语音识别、“IP 语音传输”以及语音注解功能，从而实现口授和语音命令：

备注：“英特尔® PCA 处理器”上不提供。
矢量/矩阵运算：包含针对以下用途的实用矩阵与矢量函数：

备注：“英特尔® PCA 处理器”上不提供。
密码技术：采用以下加密算法在应用程序中编写安全功能代码：

备注：“英特尔® PCA 处理器”上不提供。

此版本的新增功能

新推出 Mac OS* 版！
获取适用于 Mac OS* 应用程序的高性能数据处理与多媒体函数库 - 所有这些使用的都是您熟悉的“英特尔 IPP API”。
支持多核处理器
使用能够确保线程安全的函数以及多线程函数，让应用程序无需修改便可充分发挥最新多核处理器的优势。
新的 CPU 性能优化技术
通过使用更新的、特定于英特尔® 酷睿™ 双核与英特尔® 酷睿™ 单核处理器微体系结构的优化技术，充分发挥这些新处理器的优势。
更加丰富的视频编码示例
使用新的代码示例（演示对附加的 H.264 编解码器档案与 CABAC 编码的支持），更快地开发先进的视频应用。
更加丰富的语音编码示例：
立即使用新的 AMRWB+ 代码示例开发协作应用。

兼容性

操作系统
现已支持 Mac OS*！借助“英特尔® 集成性能原件 5.1 Mac OS* 版”，只需使用 Windows* 版与 Linux* 版所有的相同函数库 API 与函数，便可以轻松将应用程序移植到 Mac OS。
开发环境
“英特尔 IPP”非常易于使用，且可轻松集成到主流的开发工具与环境中，如 Microsoft Visual Studio*、Xcode*、Eclipse*、GCC 以及“英特尔® C++ 编译器”。

处理器
“英特尔 IPP”函数的背后是完全一致的 API，这些函数针对广泛的 32 位与 64 位微处理器进行过高度优化：

英特尔® 酷睿™ 双核处理器与英特尔® 奔腾® D 多核处理器
英特尔® 至强® 处理器
含“英特尔® EM64T”的处理器，包括 64 位英特尔至强处理器、英特尔® 奔腾® D 处理器以及英特尔® 奔腾® 处理器至尊版
英特尔® 奔腾® 4 与英特尔® 奔腾® M 处理器
基于“英特尔 XScale®”技术的处理器，包括英特尔® IXP4xx 处理器与支持“英特尔® 无线 MMX™”技术的英特尔® PXA27x 应用处理器。
英特尔® 安腾® 2 处理器

Intel IPP is validated for use with multiple generations of Intel and compatible AMD* processors, and is backed by world-class support through the Intel® Premier Support program, and by developer community forums.

Features

Multicore Processor Support
Intel IPP 6.0 fully supports today’s multicore computing platforms:

Multicore Optimized, Threaded Functions: Over 1700 critical functions for Matrix and Vector mathematics, Signal/Image Filtering and Convolutions, Image/JPEG Compression, Color Conversion and Computer Vision are internally threaded to automatically maximize performance on multi-core systems.
Multicore Optimized Code Samples: Many of the Intel IPP code samples are threaded to illustrate the effective use of Intel IPP functions in applications such as video encoding and decoding.
Fully Thread-Safe Functions: All Intel IPP functions are fully thread-safe, simplifying integration into threaded applications.

To learn more about threading and Intel IPP functions visit our threading Frequently Asked Questions (FAQ) page.

Performance-Optimized Functions
Intel IPP functions are designed to deliver performance beyond what optimized compilers alone can deliver by matching the function algorithms to low-level optimizations based on the processor’s available features such as Streaming SIMD Extensions (SSE, SSE2, SSE3, SSSE3, SSE4, and SSE4.1) and other optimized instruction sets.

Video Coding: Key algorithmic components for DV25/50/100, MPEG-2, MPEG-4, H.263, and MPEG-4 Part 10 (H.264) codecs. Figure 3 shows where Intel IPP video coding components (represented by the blue boxes) fit into the H.264 codec process flow. Functions include:

Motion Compensation
Motion Estimation
Modified Discrete Cosine Transforms
Quantization and Inverse Quantization
Entropy Coding

Image and 2D Signal Processing: Intel IPP is the premier library of image and 2D signal processing algorithms, and includes a rich selection of algorithms operating on images and regions within images (ROIs):

Transforms:
Wavelet
Fourier (FFT/DFT, real/complex)
Windowing (Hamming, Bartlett)
Discrete Cosine (DCT)

Filtering Functions:
General linear filtering
Convolution/Deconvolution (LR and FFT)
Box, Min, Max, Median
Wiener Filters
Fixed Filters (Prewitt, Sobel, Laplace, Gauss, Scharr, Roberts)
Sharpening/Hipass/Lowpass Filters

Geometric Transforms:
Resize, Mirror, Rotate, Shear
Affine transforms
Perspective transformations
Bilinear warping
Coordinate remapping

Image Statistics:
Sum, Integral, Tilted Integral
Mean, Min, Max, Histogram, StDev
Image Moments
Image Norms (L1, L2, infinity)
Image Quality Index calculation
Proximity Measures (Cross-correlations, Square Distance)
Threshold/Compare Operations

Image Arithmetic/Logic Operations:
Alpha composition
Arithmetic operations (add/sub/mul/div/sqrt/sqr/ln/exp/abs)
Logical operations (AND, OR, XOR, Shift, NOT)

Image Data Exchange/Initialization:
Copy/Set/Transpose
Channel swapping
Jaehne/Ramp/Zigzag initialization
Memory allocation for multiple image types

Computer Vision: Intel IPP includes optimized functions for many key computer-vision operations, for applications in security, machine control, media management, media annotation and more:

Feature Detection (Corner, Canny Edge Detection)
Distance Transforms
Image Gradients
Flood Filling
Motion Templates generation
Optical Flow calculation (Lucas-Kanade)

Pattern Recognition (Haar classifiers)
Pyramid functions (Gaussian/Laplacian pyramids)
Universal Pyramid functions
Camera Calibration
3D Reconstruction

Intel IPP based optimization is automatically included in the popular OpenCV open-source computer-vision library, for enhanced performance on real-time tasks, and Intel IPP was a key software component in the winner of the 2005 DARPA Grand Challenge.

Color Conversion: Today’s explosion of digital media in multiple formats brings the need to convert digital media among different color representations. Intel IPP provides a rich set of optimized color-conversion routines on 32/24/16-bit-per-pixel formats:

Color Model Conversion:
RGB, YUV, YCbCr, BGR, CbYCr, HSV,
LUV, Lab, YCC, HLS, SBGR, YCoCg,
YCCK, XYZ, CMYK

Color Format Conversions:
YCbCr422, YCbCr420, YCbCr411, CbYCr422, BGR565, BGR555, BGR565Dither

Lookup Table Conversions (Linear/Cublic/Palette)
Color to Greyscale Conversions (Fixed/Custom coefficients)
Image Bit Resolution Reductions
Color Twist Conversions (integer/float pixel values)
Gamma Corrections (Forward/Backward)

[SPAN]

String Processing: Build optimized text database management, search and retrieval, or document indexing processing into your applications using Intel IPP’s optimized string operations.

Substring substitution/insertion
String concatenation/splitting
Upper/lower case conversions

String/Substring matching
Regular Expression matching
Hash value calculation

JPEG Coding: Key algorithmic components for JPEG, JPEG 2000, and Motion JPEG codecs. Figure 4 shows where Intel IPP JPEG coding components (represented by the blue boxes) fit into the JPEG and JPEG 2000 codec process flow.

Speech Coding: Intel IPP includes a comprehensive set of routines supporting the following speech codecs/functions:

G.722.1
G.722 Sub-Band ADPCM
G.723.1
G.726
G.728
Echo Cancellation

G.729
GSM-AMR
AMR-Wideband
GSM Full Rate
Companding

The freely-downloadable Intel IPP Universal Speech Class (USC) code samples illustrate the use of the low-level Intel IPP functions to build speech codecs.

Signal Processing: Includes signal processing features for the following:

Filtering and Convolution:
Finite Impulse Response (FIR)
Infinite Impulse Response (IIR)
Median filtering
Cyclic convolution
Auto/Cross-correlation

Transforms:
Fourier (FFT, DFT, Goertzel)
Discrete Cosine Transforms (DCT)
Hilbert Transforms
Wavelet Transforms (fixed/custom filters)
Power spectrum calculation

Windowing/Sampling:
Upsampling/Downsampling
Windowing (Bartlett/Blackman/Hamming/Hann/Kaiser)

Array/Signal Initialization/Manipulation:
Move/Copy/Set/Zero
Tone/Triangle/Ramp/Jaehne Generation
Random vector generation (Uniform/Gaussian)
Array allocation
Real/Complex conversion
Polar/Cartesian conversion

Array/Signal statistics:
Sum/Max/Min/Mean/StdDev/Norm
Dot products
Thresholding
Viterbi decoding

Array Arithmetic/Logic Operations:
Arithmetic operations (add/sub/mul/div/sqrt/sqr/ln/exp/abs)
Logical operations (AND, OR, XOR, Shift, NOT)
Array sorting
Magnitude/Phase

Data Compression: In addition to video, audio and image compression with codecs, Intel IPP provides functions for lossless compression methods, such as those used in the popular “zlib” (inflate and deflate) and “libbzip2” libraries.

Burrows-Wheeler-Transform techniques:
Burrows-Wheeler Transform (BWT)
Generalized Interval Transform
Move-to-Front (MTF)
Run-length encoding (RLE)

Entropy coding:
Huffman coding
Variable-Length Coding (VLC)

Dictionary-based Compression:
LZSS encode/decode
LZ77 encode/decode

Audio Coding: Key algorithmic components for MP3,and AAC codecs. Figure 5 shows where Intel IPP JPEG coding components (represented by the blue boxes) fit into the AAC codec process flow. Functions include:

Huffman Coding
Spectral Data Pre-Quantization
Modified Discrete Cosine Transforms
Block Filtering
Frequency Domain Prediction
Spectral Band Replication
Fast Fourier Transforms

The Video and Audio code samples illustrate sample codec implementations using Intel IPP functions.[SPAN]

Speech Recognition: Build advanced speech recognition, Voice-over-IP, and voice annotation capabilities in applications, using Intel IPP’s broad range of speech-recognition capabilities:

Feature Processing
Model Evaluation
Model Estimation
Model Adaptation
Vector Quantization

Acoustic Echo Cancellation (AEC)
Polyphase Resampling
Advanced Aurora Functions
Ephraim-Malah Noise Suppression
Voice Activity Detection

Vector/Matrix Operations: Intel IPP contains a rich set of matrix and vector operations for a wide variety of applications, including physics modeling and 3D transform/lighting calculations.

Matrix algebra:
Eigenvalue/eigenvector calculation
Least Squares (QR decompositions/back-sub)
Linear Systems (LU/Cholesky)
Region-of-Interest (ROI) extraction
Fast copy of vectors/matrices

Vector algebra:
Dot products
L2 norm calculation
“saxpy” (ax + y) operations
Linear combination (ax + by)
Power/root functions
Exponential/Logarithmic/Erf/Erfc functions
Trigonometric/Hyperbolic functions
Polar/Cartesian conversion

For applications requiring high-performance linear algebra operations on very large data sets, the Intel® Math Kernel Library may also be of interest.

Cryptography: Use Intel IPP to quickly build robust, high-performance cryptographic modules and applications. Below are some of the many cryptographic building blocks included in Intel IPP’s cryptography functions.

Symmetric Ciphers:
Block Ciphers (AES/Rijndael, DES, Triple DES, Blowfish, Twofish)
Stream Ciphers (ARCFour)

One-way Hashing:
Generalized Hashing (MD5, SHA1-512)
Mask Generation (MD5, SHA1-512)

Data Authentication:
Keyed Hash (HMAC-MD5, HMAC-SHA1-512)
Data Authentication Functions (DES, TDES, Rijndael, Blowfish, Twofish)

Asymmetric Cryptography:
Elliptic curve cryptography (GF(p) and GF(2m)
RSA algorithm (RSA-OAEP, RSA-SSA)
Discrete-Logarithm Cryptography
Big-Number arithmetic
Montgomery reduction
Pseudo-random number generation
Prime number generation

Intel IPP’s cryptographic functions have been validated according to the Cryptographic Algorithm Validation Program (CAVP).

Name	Standards/Certificate
Discrete Logarithm (Digital Signature Standard)	FIPS 186-2 / Cert 190
Integer Factoring (Digital Signature Standard)	FIPS 186-2, ANSI X9.31-1998 / Cert 181
Eliptic Curve Digital Signature Algorithm (ECDSA)	FIPS 186-2, ANSI X9.62-1998 / Cert 40
Random Number Generator	FIPS 186-2 / Cert 245

Note: To access the Cryptography Library, you must request access from Intel.

Ray-Tracing and Rendering: Core operations used in ray-tracing, realistic image rendering, and physics applications:

Bounding-box calculations
Object-ray intersections
Shadow/Reflection calculations

Data Integrity: Error correcting codes are vitally important to preserving the integrity of data in transmission, storage and encoding. For example transmission lines can be unreliable and introduce data errors, spurious signals can occur when saving data to a compact disk, and errors can occur when reading bar codes. Using error correcting codes like Reed-Solomon is a good way to correct these errors.

System Requirements
Please refer to the section below for installation requirements and system requirements that match your application’s target platform.[SPAN]

Application Target Platforms

32-bit Intel® architecture Platforms

Intel® Core i7™ processor family

Intel® Atom™ processor family

Intel® Core™ 2 processor family(including 45nm processors)

Intel Core processor family

Intel® Pentium® M processors

Intel ultra-mobile processors (A100, A110, and 45 nm processors)

Intel Pentium D processor

Intel® Pentium® 4 processor

Intel® Xeon® processors(3000, 5000, 7000 series)

Other compatible processors such as AMD Athlon* and Opteron* processors

64-bit Intel 64 architecture-based platforms

Intel® Core i7™ processor family

Intel® Atom™ processor family

Intel Core 2 processor family (including 45nm processors)

Intel ultra-mobile processors (45 nm processors)

Intel Pentium D processor

Intel Pentium 4 processor

Intel Xeon processors(3000, 5000, 7000 series)

Other compatible processors such as AMD Athlon and Opteron processors

64-bit IA-64 architecture-based platforms

Intel® Itanium® processors

32-bit IA-32 Architecture-Based and Compatible Platforms
(Intel Core 2 processor family, Intel Core processor family, Intel Pentium processors, and compatible AMD processors)

	OS Version	Supported Compilers
Microsoft Windows	Microsoft Windows Vista* Microsoft Windows* XP Microsoft Windows Server* 2008 Microsoft Windows Server* 2003	Intel® C++ Compiler for Windows* OS version 10.1 and 11.0 Microsoft Visual Studio* 2008 Microsoft Visual Studio* 2005 Microsoft Visual C++* .NET 2003 Microsoft Windows* Software Development Kit for Microsoft Windows Vista*
Linux	Linux system with glibc 2.2.4, 2.2.5, 2.2.93, 2.3.2 or 2.3.3 and the 2.4.X or 2.6.X Linux kernel as represented by the following distributions. Note: Not all distributions listed are validated and not all distributions are listed. Red Hat Enterprise Linux* OS 2.1, 3, or 4 SUSE* Linux 8.2, 9.1 SUSE Linux Enterprise Server* 8 or 9 Debian* 4.0r1 Ubuntu* 7.10 Asianux* Server 3.0 Red Flag* 5.0	Intel® C++ Compiler version 10.1 and 11.0 for Linux * for IA-32 architecture Linux Developer tools component installed, including gcc, g++ and related tools
Mac OS X	10.4.3 or later	Intel C++ Compiler 10.1 and 11.0 for Mac OS X, including Professional Edition GNU Compiler Collection 4.0 or later

64-bit Intel 64 Architecture-Based Platforms
(Intel Core 2 processor family, Intel Pentium D processors, Intel Xeon processors, and processors from AMD compatible with Intel 64 architecture)

	OS Version	Supported Compilers
Microsoft Windows	Microsoft Windows Vista* Microsoft Windows* XP Microsoft Windows Server* 2008 Microsoft Windows Server* 2003	Intel® C++ Compiler for Windows* OS version 10.1 and 11.0 for processors based on Intel® 64 architecture Microsoft Visual Studio* 2008 Microsoft Visual Studio* 2005 Microsoft Platform SDK, Version 3790.1830 (April 2005) Microsoft Platform SDK R2, Version 3790.2075 (March 2006)
Linux	Linux system with glibc 2.2.4, 2.2.5, 2.2.93, 2.3.2 or 2.3.3 and the 2.4.X or 2.6.X Linux kernel as represented by the following distributions. Note: Not all distributions listed are validated and not all distributions are listed. Red Hat Enterprise Linux* OS 3 or 4 SUSE Linux Enterprise Server* 9 Debian* 4.0r1 Ubuntu* 7.10 Asianux* Server 3.0 Red Flag* 5.0	Intel C++ Compiler 10.1 or 11.0 for Linux Linux Developer Tools installed, including gcc, g++, and related tools
Mac OS X	10.4.6 or later	Intel C++ Compiler 10.1 and 11.0 for Mac OS X GNU Compiler Collection 4.0 or later

[SPAN]

64-bit IA-64 Architecture-Based Platforms
(Intel® Itanium® processors)

OS Version

Supported Compilers

Microsoft Windows

Microsoft Windows Server 2008

Microsoft Windows Server 2003

Intel® C++ Compiler for Windows* OS version 10.1 and 11.0 for Intel Itanium Processors

Microsoft Platform SDK, Version 3790.1830 (April 2005)

Microsoft Platform SDK R2, Version 3790.2075 (March 2006)

Linux

Linux system with glibc 2.2.4, 2.2.5, 2.2.93, 2.3.2 or 2.3.3 and the 2.4.X or 2.6.X Linux kernel as represented by the following distributions. Note: Not all distributions listed are validated and not all distributions are listed.

Red Hat Enterprise Linux* OS 2.1, 3, or 4
SUSE Linux Enterprise Server* 8 or 9
Debian* 4.0r1
Ubuntu* 7.10
Asianux* Server 3.0
Red Flag* 5.0

Intel C++ Compiler 10.1 and 11.0 for Linux

Linux Developer Tools installed, including gcc, g++, and related tools

Intel Atom Architecture-based Platforms

OS Version

Supported Compilers

Linux

Linux system with glibc 2.2.4, 2.2.5, 2.2.93, 2.3.2 or 2.3.3 and the 2.4.X or 2.6.X Linux kernel as represented by the following distributions.

Note: Not all distributions listed are validated and not all distributions are listed.

Ubuntu* 7.10
Red Flag* 5.0

Intel® C++ Compiler version 10.1 & 11.0 for Linux* OS for IA-32 processors

Linux Developer tools component installed, including gcc, g++ and related tools

Installation Requirements

	Supported Software / Hardware
Operating Systems	Microsoft Windows: Windows Vista Windows XP, SP1 or SP2 Windows Server 2003, SP1 or SP2 Linux: Ubuntu 6.04, 7.10 Debian 3.1r5, 4.0 Red Hat Enterprise Linux* 3, 4 and 5 Red Hat Fedora Core 4, 5 SUSE Linux Enterprise Server* 9 or 10 Red Flag DC Server 5.0 Mandriva 10.1 Mac OS X: Version 10.4.3 or later
Processor Requirements	IA-32 architecture-based and compatible platforms: Intel® Pentium® III processor or later, 400MHz or faster Any Intel Core family processor Any Intel Xeon processor Compatible AMD processors Intel 64 architecture-based and compatible platforms: Any Intel Core family processor Any Intel Xeon processor Any Intel Pentium D processor Compatible AMD processors Intel Itanium processor-based platforms: Any Intel Itanium processor Intel Atom processor-based platforms: Any Intel Atom family processor
Minimum Disk Space for Install	900 MB plus 300 MB of temporary space during installation for each Application Target Platform