Building Intel® Integrated Performance Primitives Cryptography...

Developer Guide and Reference for Intel® Integrated Performance Primitives Cryptography

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ID 790813

Date 6/24/2024

Version

Public

Visible to Intel only — GUID: GUID-A51D08C0-4985-4313-BBBD-9C66F09D959E

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Building Intel® Integrated Performance Primitives Cryptography Applications

The code example below represents a short application to help you get started with Intel® Integrated Performance Primitives Cryptography (Intel® IPP Cryptography):


#include "ippcp.h"
#include <stdio.h>
int main(int argc, char* argv[])
{
   const IppLibraryVersion *lib;
   IppStatus status;
   Ipp64u mask, emask;


   /* Get Intel® Integrated Performance Primitives Cryptography */
   /*(Intel® IPP Cryptography) library version info */
   lib = ippcpGetLibVersion();
   printf("%s %s\n", lib->Name, lib->Version);


   /* Get CPU features and features enabled with selected library level */
   status = ippcpGetCpuFeatures( &mask );
   if( ippStsNoErr == status ) {
      emask = ippcpGetEnabledCpuFeatures();
      printf("Features supported by CPU\tby Intel® IPP Cryptography\n");
      printf("-----------------------------------------\n");
      printf("  ippCPUID_MMX        = ");
      printf("%c\t%c\t",( mask & ippCPUID_MMX ) ? 'Y':'N',( emask & ippCPUID_MMX ) ? 'Y':'N');
      printf("Intel® Architecture MMX technology supported\n");
      printf("  ippCPUID_SSE        = ");
      printf("%c\t%c\t",( mask & ippCPUID_SSE ) ? 'Y':'N',( emask & ippCPUID_SSE ) ? 'Y':'N');
      printf("Intel® Streaming SIMD Extensions\n");
      printf("  ippCPUID_SSE2       = ");
      printf("%c\t%c\t",( mask & ippCPUID_SSE2 ) ? 'Y':'N',( emask & ippCPUID_SSE2 ) ? 'Y':'N');
      printf("Intel® Streaming SIMD Extensions 2\n");
      printf("  ippCPUID_SSE3       = ");
      printf("%c\t%c\t",( mask & ippCPUID_SSE3 ) ? 'Y':'N',( emask & ippCPUID_SSE3 ) ? 'Y':'N');
      printf("Intel® Streaming SIMD Extensions 3\n");
      printf("  ippCPUID_SSSE3      = ");
      printf("%c\t%c\t",( mask & ippCPUID_SSSE3 ) ? 'Y':'N',( emask & ippCPUID_SSSE3 ) ? 'Y':'N');
      printf("Intel® Supplemental Streaming SIMD Extensions 3\n");
      printf("  ippCPUID_MOVBE      = ");
      printf("%c\t%c\t",( mask & ippCPUID_MOVBE ) ? 'Y':'N',( emask & ippCPUID_MOVBE ) ? 'Y':'N');
      printf("The processor supports MOVBE instruction\n");
      printf("  ippCPUID_SSE41      = ");
      printf("%c\t%c\t",( mask & ippCPUID_SSE41 ) ? 'Y':'N',( emask & ippCPUID_SSE41 ) ? 'Y':'N');
      printf("Intel® Streaming SIMD Extensions 4.1\n");
      printf("  ippCPUID_SSE42      = ");
      printf("%c\t%c\t",( mask & ippCPUID_SSE42 ) ? 'Y':'N',( emask & ippCPUID_SSE42 ) ? 'Y':'N');
      printf("Intel® Streaming SIMD Extensions 4.2\n");
      printf("  ippCPUID_AVX        = ");
      printf("%c\t%c\t",( mask & ippCPUID_AVX ) ? 'Y':'N',( emask & ippCPUID_AVX ) ? 'Y':'N');
      printf("Intel® Advanced Vector Extensions instruction set\n");
      printf("  ippAVX_ENABLEDBYOS  = ");
      printf("%c\t%c\t",( mask & ippAVX_ENABLEDBYOS ) ? 'Y':'N',( emask & ippAVX_ENABLEDBYOS ) ? 'Y':'N');
      printf("The operating system supports Intel® AVX\n");
      printf("  ippCPUID_AES        = ");
      printf("%c\t%c\t",( mask & ippCPUID_AES ) ? 'Y':'N',( emask & ippCPUID_AES ) ? 'Y':'N');
      printf("Intel® Advanced Encryption Standard New Instructions\n");
      printf("  ippCPUID_SHA        = ");
      printf("%c\t%c\t",( mask & ippCPUID_SHA ) ? 'Y':'N',( emask & ippCPUID_SHA ) ? 'Y':'N');
      printf("Intel® Secure Hash Algorithm - New Instructions (Intel® SHA-NI)\n");
      printf("  ippCPUID_CLMUL      = ");
      printf("%c\t%c\t",( mask & ippCPUID_CLMUL ) ? 'Y':'N',( emask & ippCPUID_CLMUL ) ? 'Y':'N');
      printf("PCLMULQDQ instruction\n");
      printf("  ippCPUID_RDRAND     = ");
      printf("%c\t%c\t",( mask & ippCPUID_RDRAND ) ? 'Y':'N',( emask & ippCPUID_RDRAND ) ? 'Y':'N');
      printf("Read Random Number instructions\n");
      printf("  ippCPUID_F16C       = ");
      printf("%c\t%c\t",( mask & ippCPUID_F16C ) ? 'Y':'N',( emask & ippCPUID_F16C ) ? 'Y':'N');
      printf("Float16 instructions\n");
      printf("  ippCPUID_AVX2       = ");
      printf("%c\t%c\t",( mask & ippCPUID_AVX2 ) ? 'Y':'N',( emask & ippCPUID_AVX2 ) ? 'Y':'N');
      printf("Intel® Advanced Vector Extensions 2 instruction set\n");
      printf("  ippCPUID_AVX512F    = ");
      printf("%c\t%c\t",( mask & ippCPUID_AVX512F ) ? 'Y':'N',( emask & ippCPUID_AVX512F ) ? 'Y':'N');
      printf("Intel® Advanced Vector Extensions 3.1 instruction set\n");
      printf("  ippCPUID_AVX512CD   = ");
      printf("%c\t%c\t",( mask & ippCPUID_AVX512CD ) ? 'Y':'N',( emask & ippCPUID_AVX512CD ) ? 'Y':'N');
      printf("Intel® Advanced Vector Extensions CD (Conflict Detection) instruction set\n");
      printf("  ippCPUID_AVX512ER   = ");
      printf("%c\t%c\t",( mask & ippCPUID_AVX512ER ) ? 'Y':'N',( emask & ippCPUID_AVX512ER ) ? 'Y':'N');
      printf("Intel® Advanced Vector Extensions ER instruction set\n");
      printf("  ippCPUID_ADCOX      = ");
      printf("%c\t%c\t",( mask & ippCPUID_ADCOX ) ? 'Y':'N',( emask & ippCPUID_ADCOX ) ? 'Y':'N');
      printf("ADCX and ADOX instructions\n");
      printf("  ippCPUID_RDSEED     = ");
      printf("%c\t%c\t",( mask & ippCPUID_RDSEED ) ? 'Y':'N',( emask & ippCPUID_RDSEED ) ? 'Y':'N');
      printf("The RDSEED instruction\n");
      printf("  ippCPUID_PREFETCHW  = ");
      printf("%c\t%c\t",( mask & ippCPUID_PREFETCHW ) ? 'Y':'N',( emask & ippCPUID_PREFETCHW ) ? 'Y':'N');
      printf("The PREFETCHW instruction\n");
      printf("  ippCPUID_KNC        = ");
      printf("%c\t%c\t",( mask & ippCPUID_KNC ) ? 'Y':'N',( emask & ippCPUID_KNC ) ? 'Y':'N');
      printf("Intel® Xeon Phi™ Coprocessor instruction set\n");
   }
   return 0;
}

This application consists of three sections:

Initialize the Intel IPP Cryptography library. The Intel IPP Cryptography library is auto-initialized with the first call of an Intel IPP Cryptography function.

In certain debugging scenarios, it is helpful to force a specific implementation layer using ippcpSetCpuFeatures(), instead of the best as chosen by the dispatcher.
Get the library layer name and version. You can also get the version information using the ippcpversion.h file located in the /include directory.
Show the hardware optimizations used by the selected library layer and supported by CPU.

Building the First Example on Windows* OS

To build the code example above on Windows* OS, follow the steps:

Start Microsoft Visual Studio* and create an empty C++ project.
Add a new c file and paste the code into it.
Set the include directories and the linking model as described in Linking Your Microsoft* Visual Studio* Project with Intel IPP Cryptography.
Compile and run the application.

Building the First Example on Linux* OS

To build the code example above on Linux* OS, follow the steps:

Paste the code into the editor of your choice.
Make sure the compiler and Intel IPP Cryptography variables are set in your shell. For information on how to set environment variables see Setting Environment Variables.

Compile with the following command:

Intel® 64


icc ippcptest.cpp -o ippcptest -I $IPPCRYPTOROOT/include -L $IPPCRYPTOROOT/lib -lippcp.

IA-32


icc ippcptest.cpp -o ippcptest -I $IPPCRYPTOROOT/include -L $IPPCRYPTOROOT/lib32 -lippcp.

For more information, see Linking Options.

Run the application.

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Developer Guide and Reference for Intel® Integrated Performance Primitives Cryptography

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