Freescale Semiconductor SEC2SWUG specifications Ipsecaesecbreq

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Individual Request Type Descriptions

Table 26. IPSEC_AES_CBC_REQ Valid Descriptors (opId) (continued)

Descriptors

Value

Function Description

DPD_IPSEC_AES_CBC_ENCRYPT_MD5

0x8003

Perform the IPSec process of encrypting in AES

 

 

using CBC mode with MD5

DPD_IPSEC_AES_CBC_ENCRYPT_SHA

0x8004

Perform the IPSec process of encrypting in AES

 

 

using CBC mode with SHA-1

DPD_IPSEC_AES_CBC_ENCRYPT_SHA256

0x8005

Perform the IPSec process of encrypting in AES

 

 

using CBC mode with SHA-256

DPD_IPSEC_AES_CBC_DECRYPT_MD5_APAD

0x8006

Perform the IPSec process of decrypting in AES

 

 

using CBC mode with MD5 auto padding

DPD_IPSEC_AES_CBC_DECRYPT_SHA_APAD

0x8007

Perform the IPSec process of decrypting in AES

 

 

using CBC mode with SHA-1 auto padding

DPD_IPSEC_AES_CBC_DECRYPT_SHA256_APAD

0x8008

Perform the IPSec process of decrypting in AES

 

 

using CBC mode with SHA-256 auto padding

DPD_IPSEC_AES_CBC_DECRYPT_MD5

0x8009

Perform the IPSec process of decrypting in AES

 

 

using CBC mode with MD5

DPD_IPSEC_AES_CBC_DECRYPT_SHA

0x800A

Perform the IPSec process of decrypting in AES

 

 

using CBC mode with SHA-1

DPD_IPSEC_AES_CBC_DECRYPT_SHA256

0x800B

Perform the IPSec process of decrypting in AES

 

 

using CBC mode with SHA-256

4.9.4 IPSEC_AES_ECB_REQ

COMMON_REQ_PREAMBLE

unsigned long hashKeyBytes; unsigned char *hashKeyData; unsigned long cryptKeyBytes; unsigned char *cryptKeyData; unsigned long hashInDataBytes; unsigned char *hashInData; unsigned long inDataBytes; unsigned char *inData; unsigned char *cryptDataOut; unsigned long hashDataOutBytes; unsigned char *hashDataOut;

NUM_IPSEC_AES_ECB_DESC defines the number of descriptors within the DPD_IPSEC_AES_ECB_GROUP that use

this request.

DPD_IPSEC_AES_ECB_GROUP (0x8100) defines the group for all descriptors within this request.

SEC 2.0 Reference Device Driver User’s Guide, Rev. 0

Freescale Semiconductor

PRELIMINARY—SUBJECT TO CHANGE WITHOUT NOTICE

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Contents Freescale Semiconductor OverviewSEC 2.0 Reference Device Driver User’s Guide, Rev Acronyms and AbbreviationsOverview Term MeaningEnd-User Application Device Driver ComponentsDevice Driver Structure Device Driver ComponentsProcess Request Routine Interrupt Service RoutineDriver Initialization Routine Request Dispatch RoutineUser Interface Deferred Service RoutineUser Interface Application Interface= Dpdaesacbcencryptcrypt Error HandlingSecond and Third Arguments in the ioctl Function Global Definitions1 I/O Control Codes Channel DefinitionsChannel Defines Callback Error Status Return CodeOperation ID opId Masks Return CodesSEC2TEAERROR SEC2ADDRESSPROBLEMSEC2CHAERROR SEC2PARITYSYSTEMERRORDefine Description SEC2CANCELLEDREQUESTMiscellaneous Request Structures SEC2INVALIDADDRESSStatusreq Process Request StructuresScatter-Gather Buffer Management NotifyonerrorDirect Scatter-Gather Usage Example Rngreq Individual Request Type DescriptionsRandom Number Requests DES RequestsDescbccryptreq Valid Descriptors opId ARC4 RequestsDescryptreq 1 ARC4LOADCTXCRYPTREQARC4LOADCTXCRYPTREQ Valid Descriptor opId 2 ARC4LOADKEYCRYPTUNLOADCTXREQARC4LOADKEYCRYPTUNLOADCTXREQ Valid Descriptor opId Hashreq Hash RequestsHashreq Valid Descriptors 0x4400 opId Hmacpadreq Hmac RequestsHashreq Valid Descriptors 0x4500 opId Aesacryptreq AES RequestsHmacpadreq Valid Descriptors opId Modexpreq Valid Descriptor opId Integer Public Key RequestsModexpreq Aesacryptreq Valid Descriptors opIdDpdmmssrsaexp ModssexpreqMODR2MODNREQ Modssexpreq Valid Descriptor opId0x5300 Modrrmodpreq5 MOD2OPREQ Modrrmodpreq Valid Descriptor opIdMOD2OPREQ Valid Descriptors opId Value Function Description Eccpointreq ECC Public Key RequestsMOD2OPREQ Valid Descriptors opId Eccpointreq Valid Descriptors opId 2 ECC2OPREQDpdecspkbuildulctx EccspkbuildreqECC2OPREQ Valid Descriptors opId Eccspkbuildreq Valid Descriptor opIdEccptadddblreq Valid Descriptor opId IPSec RequestsEccptadddblreq IpseccbcreqIpseccbcreq Valid Descriptors opId Descriptors Ipsececbreq Valid Descriptors opId IpsececbreqIpsecaescbcreq Valid Descriptors opId IpsecaescbcreqIpsecaesecbreq Ipsecaesecbreq Valid Descriptors opId IpsecespreqIpsecespreq Valid Descriptors opId DPDIPSECESPINTDESCBCDCRPTMD5PAD DpdipsecespinsdescbcdcrptshapadDPDIPSECESPOUTTDESCBCCRPTMD5PAD DpdipsecespouttdescbccrptshapadSrtpreq 10 802.11 Protocol RequestsSrtp Protocol Requests CcmpreqDES Sample Sample CodeSrtpreq Valid Descriptors opId Ipsec Sample PRELIMINARY-SUBJECT to Change Without Notice Linux Environment InstallationOperation VxWorks Environment Driver Operation in User ModeVxWorks Environment Driver Module License MacroVxWorks Interface Module Variables PortingBuilding the Interface Modules BSP IntegrationHeader Files Interrupt Service RoutineSource Files Debug Messaging Conditional CompilationDistribution Archive How to Reach Us

SEC2SWUG specifications

Freescale Semiconductor, a prominent player in the semiconductor industry, has made significant strides in developing robust solutions tailored for the automotive and industrial sectors. One such innovation is the SEC2SWUG (Security Configuration to Software User Guide), a comprehensive framework designed to enhance security protocols across various applications.

The SEC2SWUG is particularly vital in an era where cybersecurity threats are increasingly sophisticated. This tool is built to help developers implement security measures seamlessly during the software design phase, ensuring products are resilient against potential vulnerabilities. One of the main features of the SEC2SWUG is its versatility; it can be applied across a wide range of microcontrollers and processors offered by Freescale. This is particularly advantageous for engineers who require a consistent security approach across different platforms.

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Another key characteristic of SEC2SWUG is its user-friendliness. Freescale has focused on creating a resource that not only provides theoretical knowledge but also practical guidelines, making it easier for developers to integrate security protocols into their projects. The guide features clear annotations, example code snippets, and troubleshooting tips, which enhance the developer experience and facilitate a smoother transition from concept to execution.

Additionally, SEC2SWUG is designed to be scalable. As industries evolve, the demand for security measures will only grow, and this framework ensures that developers can adapt their solutions accordingly. Whether working on embedded systems, IoT applications, or complex automotive networks, the SEC2SWUG offers a robust security foundation.

In conclusion, Freescale Semiconductor's SEC2SWUG is a vital tool for engineers and developers looking to embed security into their applications. With its focus on advanced technologies and user-centric design, the SEC2SWUG stands at the forefront of secure software development, addressing the critical need for safety in interconnected systems.