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Network Working Group J. Ross Request for Comments: 3125 Security & Standards Category: Experimental D. Pinkas Integris N. Pope Security & Standards September 2001 Electronic Signature Policies Status of this Memo This memo defines an Experimental Protocol for the Internet community. It does not specify an Internet standard of any kind. Discussion and suggestions for improvement are requested. Distribution of this memo is unlimited. Copyright Notice Copyright (C) The Internet Society (2001). All Rights Reserved. Abstract This document defines signature policies for electronic signatures. A signature policy is a set of rules for the creation and validation of an electronic signature, under which the validity of signature can be determined. A given legal/contractual context may recognize a particular signature policy as meeting its requirements. A signature policy has a globally unique reference, which is bound to an electronic signature by the signer as part of the signature calculation. The signature policy needs to be available in human readable form so that it can be assessed to meet the requirements of the legal and contractual context in which it is being applied. To allow for the automatic processing of an electronic signature another part of the signature policy specifies the electronic rules for the creation and validation of the electronic signature in a computer processable form. In the current document the format of the signature policy is defined using ASN.1. The contents of this document is based on the signature policy defined in ETSI TS 101 733 V.1.2.2 (2000-12) Copyright (C). Individual copies of this ETSI deliverable can be downloaded from http://www.etsi.org. Ross, et al. Experimental [Page 1]
RFC 3125 Electronic Signature Policies September 2001 Table of Contents 1. Introduction 3 2. Major Parties 3 3. Signature Policy Specification 5 3.1 Overall ASN.1 Structure 5 3.2 Signature Validation Policy 6 3.3 Common Rules 7 3.4 Commitment Rules 8 3.5 Signer and Verifier Rules 9 3.5.1 Signer Rules 9 3.5.2 Verifier Rules 11 3.6 Certificate and Revocation Requirements 11 3.6.1 Certificate Requirements 11 3.6.2 Revocation Requirements 13 3.7 Signing Certificate Trust Conditions 14 3.8 Time-Stamp Trust Conditions 15 3.9 Attribute Trust Conditions 16 3.10 Algorithm Constraints 17 3.11 Signature Policy Extensions 18 4. Security Considerations 18 4.1 Protection of Private Key 18 4.2 Choice of Algorithms 18 5. Conformance Requirements 19 6. References 19 7. Authors' Addresses 20 Annex A (normative): 21 A.1 Definitions Using X.208 (1988) ASN.1 Syntax 21 A.2 Definitions Using X.680 (1997) ASN.1 Syntax 27 Annex B (informative): 34 B.1 Signature Policy and Signature Validation Policy 34 B.2 Identification of Signature Policy 36 B.3 General Signature Policy Information 36 B.4 Recognized Commitment Types 37 B.5 Rules for Use of Certification Authorities 37 B.5.1 Trust Points 38 B.5.2 Certification Path 38 B.6 Revocation Rules 39 B.7 Rules for the Use of Roles 39 B.7.1 Attribute Values 39 B.7.2 Trust Points for Certified Attributes 40 B.7.3 Certification Path for Certified Attributes 40 B.8 Rules for the Use of Time-Stamping and Timing 40 B.8.1 Trust Points and Certificate Paths 41 B.8.2 Time-Stamping Authority Names 41 B.8.3 Timing Constraints - Caution Period 41 B.8.4 Timing Constraints - Time-Stamp Delay 41 B.9 Rules for Verification Data to be followed 41 Ross, et al. Experimental [Page 2]
RFC 3125 Electronic Signature Policies September 2001 B.10 Rules for Algorithm Constraints and Key Lengths 42 B.11 Other Signature Policy Rules 42 B.12 Signature Policy Protection 42 Full Copyright Statement 44 1. Introduction This document is intended to cover signature policies which can be used with electronic signatures for various types of transactions, including business transactions (e.g., purchase requisition, contract, and invoice applications). Electronic signatures can be used for any transaction between an individual and a company, between two companies, between an individual and a governmental body, etc. This document is independent of any environment. It can be applied to any environment e.g., smart cards, GSM SIM cards, special programs for electronic signatures etc. The key words "MUST", "MUST NOT", "REQUIRED", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this document (in uppercase, as shown) are to be interpreted as described in [RFC2119]. 2. Major Parties The document uses the following terms: * the Signature Policy Issuer; * the Signer; * the Verifier; * the Arbitrator; * Trusted Service Providers (TSP); The Signature Policy Issuer (which is a Trusted Service Provider (TSP)) issues signatures policies that define the technical and procedural requirements for electronic signature creation, and validation/ verification, in order to meet a particular business need. The Signer is the entity that creates the electronic signature. When the signer digitally signs over an signature policy identifier, it represents a commitment on behalf of the signing entity that the data being signed is signed under the rules defined by the signature policy. The Verifier is the entity that validates the electronic signature, it may be a single entity or multiple entities. The verifier MUST validate the electronic signature under the rules defined by the electronic signature policy for the signature to be valid. Ross, et al. Experimental [Page 3]
RFC 3125 Electronic Signature Policies September 2001 An arbitrator, is an entity which arbitrates disputes between a signer and a verifier. It acts as verifier when it verifies the electronic signature after it has been previously validated. The Trusted Service Providers (TSPs) are one or more entities that help to build trust relationships between the signer and verifier. Use of TSP specific services MAY be mandated by signature policy. TSP supporting services include: user certificates, cross- certificates, time-stamping tokens,CRLs, ARLs, OCSP responses. A Trusted Service Providers (TSPs) MAY be a Signature Policy Issuer, as Such, the TSP MUST define the technical and procedural requirements for electronic signature creation and validation, in order to meet a particular business need. The following other TSPs are used to support the functions defined in this document: * Certification Authorities; * Registration Authorities; * Repository Authorities (e.g., a Directory); * Time-Stamping Authorities; * One-line Certificate Status Protocol responders; * Attribute Authorities. Certification Authorities provide users with public key certificates. Registration Authorities allows the registration of entities before a CA generates certificates. Repository Authorities publish CRLs issued by CAs, , cross- certificates (i.e., CA certificates) issued by CAs, signature policies issued by Signature Policy Issuers and optionally public key certificates (i.e., leaf certificates) issued by CAs. Time-Stamping Authorities attest that some data was formed before a given trusted time. One-line Certificate Status Protocol responders (OSCP responders) provide information about the status (i.e., revoked, not revoked, unknown) of a particular certificate. Attributes Authorities provide users with attributes linked to public key certificates An Arbitrator is an entity that arbitrates disputes between a signer and a verifier. Ross, et al. Experimental [Page 4]
RFC 3125 Electronic Signature Policies September 2001 3. Signature Policy Specification A signature policy specification includes general information about the policy, the validation policy rules and other signature policy information. This document mandates that: * an electronic signature must be processed by the signer and verifier in accordance with the signature policy referenced by the signer; * the signature policy referenced by the signer must be identifiable by an Object Identifier; * there must exist a specification of the signature policy; * for a given signature policy there must be one definitive form of the specification which has a unique binary encoding; * a hash of the definitive specification, using an agreed algorithm, must be provided by the signer and checked by the verifier. This document defines but does not mandate the form of the signature policy specification. The signature policy may be specified either: * in a free form document for human interpretation; or * in a structured form using an agreed syntax and encoding. This document defines an ASN.1 based syntax that may be used to define a structured signature policy. Future versions of this document may include structured a signature policy specification using XML. 3.1 Overall ASN.1 Structure The overall structure of a signature policy defined using ASN.1 is given in this section. Use of this ASN.1 structure is optional. This ASN.1 syntax is encoded using the Distinguished Encoding Rules (DER). In this structure the policy information is preceded by an identifier for the hashing algorithm used to protect the signature policy and followed by the hash value which must be re-calculated and checked whenever the signature policy is passed between the issuer and signer/verifier. The hash is calculated without the outer type and length fields. Ross, et al. Experimental [Page 5]
RFC 3125 Electronic Signature Policies September 2001 SignaturePolicy ::= SEQUENCE { signPolicyHashAlg AlgorithmIdentifier, signPolicyInfo SignPolicyInfo, signPolicyHash SignPolicyHash OPTIONAL } SignPolicyHash ::= OCTET STRING SignPolicyInfo ::= SEQUENCE { signPolicyIdentifier SignPolicyId, dateOfIssue GeneralizedTime, policyIssuerName PolicyIssuerName, fieldOfApplication FieldOfApplication, signatureValidationPolicy SignatureValidationPolicy, signPolExtensions SignPolExtensions OPTIONAL } SignPolicyId ::= OBJECT IDENTIFIER PolicyIssuerName ::= GeneralNames FieldOfApplication ::= DirectoryString The policyIssuerName field identifies the policy issuer in one or more of the general name forms. The fieldofApplication is a description of the expected application of this policy. The signature validation policy rules are fully processable to allow the validation of electronic signatures issued under that form of signature policy. They are described in the rest of this section. The signPolExtensions is a generic way to extend the definition of any sub-component of a signature policy. 3.2 Signature Validation Policy The signature validation policy defines for the signer which data elements must be present in the electronic signature he provides and for the verifier which data elements must be present under that signature policy for an electronic signature to be potentially valid. The signature validation policy is described as follows: Ross, et al. Experimental [Page 6]
RFC 3125 Electronic Signature Policies September 2001 SignatureValidationPolicy ::= SEQUENCE { signingPeriod SigningPeriod, commonRules CommonRules, commitmentRules CommitmentRules, signPolExtensions SignPolExtensions OPTIONAL } The signingPeriod identifies the date and time before which the signature policy SHOULD NOT be used for creating signatures, and an optional date after which it should not be used for creating signatures. SigningPeriod ::= SEQUENCE { notBefore GeneralizedTime, notAfter GeneralizedTime OPTIONAL } 3.3 Common Rules The CommonRules define rules that are common to all commitment types. These rules are defined in terms of trust conditions for certificates, time-stamps and attributes, along with any constraints on attributes that may be included in the electronic signature. CommonRules ::= SEQUENCE { signerAndVeriferRules [0] SignerAndVerifierRules OPTIONAL, signingCertTrustCondition [1] SigningCertTrustCondition OPTIONAL, timeStampTrustCondition [2] TimestampTrustCondition OPTIONAL, attributeTrustCondition [3] AttributeTrustCondition OPTIONAL, algorithmConstraintSet [4] AlgorithmConstraintSet OPTIONAL, signPolExtensions [5] SignPolExtensions OPTIONAL } If a field is present in CommonRules then the equivalent field must not be present in any of the CommitmentRules (see below). If any of the following fields are not present in CommonRules then it must be present in each CommitmentRule: * signerAndVeriferRules; * signingCertTrustCondition; * timeStampTrustCondition. Ross, et al. Experimental [Page 7]
RFC 3125 Electronic Signature Policies September 2001 3.4 Commitment Rules The CommitmentRules consists of the validation rules which apply to given commitment types: CommitmentRules ::= SEQUENCE OF CommitmentRule The CommitmentRule for given commitment types are defined in terms of trust conditions for certificates, time-stamps and attributes, along with any constraints on attributes that may be included in the electronic signature. CommitmentRule ::= SEQUENCE { selCommitmentTypes SelectedCommitmentTypes, signerAndVeriferRules [0] SignerAndVerifierRules OPTIONAL, signingCertTrustCondition [1] SigningCertTrustCondition OPTIONAL, timeStampTrustCondition [2] TimestampTrustCondition OPTIONAL, attributeTrustCondition [3] AttributeTrustCondition OPTIONAL, algorithmConstraintSet [4] AlgorithmConstraintSet OPTIONAL, signPolExtensions [5] SignPolExtensions OPTIONAL } SelectedCommitmentTypes ::= SEQUENCE OF CHOICE { empty NULL, recognizedCommitmentType CommitmentType } If the SelectedCommitmentTypes indicates "empty" then this rule applied when a commitment type is not present (i.e., the type of commitment is indicated in the semantics of the message). Otherwise, the electronic signature must contain a commitment type indication that must fit one of the commitments types that are mentioned in CommitmentType. A specific commitment type identifier must not appear in more than one commitment rule. CommitmentType ::= SEQUENCE { identifier CommitmentTypeIdentifier, fieldOfApplication [0] FieldOfApplication OPTIONAL, semantics [1] DirectoryString OPTIONAL } Ross, et al. Experimental [Page 8]
RFC 3125 Electronic Signature Policies September 2001 The fieldOfApplication and semantics fields define the specific use and meaning of the commitment within the overall field of application defined for the policy. 3.5 Signer and Verifier Rules The following rules apply to the format of electronic signatures defined using [ES-FORMATS]. The SignerAndVerifierRules consists of signer rule and verification rules as defined below: SignerAndVerifierRules ::= SEQUENCE { signerRules SignerRules, verifierRules VerifierRules } 3.5.1 Signer Rules The signer rules identify: * if the eContent is empty and the signature is calculated using a hash of signed data external to CMS structure. * the CMS signed attributes that must be provided by the signer under this policy; * the CMS unsigned attribute that must be provided by the signer under this policy; * whether the certificate identifiers from the full certification path up to the trust point must be provided by the signer in the SigningCertificate attribute; * whether a signer's certificate, or all certificates in the certification path to the trust point must be by the signer in the * certificates field of SignedData. SignerRules ::= SEQUENCE { externalSignedData BOOLEAN OPTIONAL, -- True if signed data is external to CMS structure -- False if signed data part of CMS structure -- Not present if either allowed mandatedSignedAttr CMSAttrs, -- Mandated CMS signed attributes mandatedUnsignedAttr CMSAttrs, -- Mandated CMS unsigned attributed mandatedCertificateRef [0] CertRefReq DEFAULT signerOnly, -- Mandated Certificate Reference Ross, et al. Experimental [Page 9]
RFC 3125 Electronic Signature Policies September 2001 mandatedCertificateInfo [1] CertInfoReq DEFAULT none, -- Mandated Certificate Info signPolExtensions [2] SignPolExtensions OPTIONAL } CMSattrs ::= SEQUENCE OF OBJECT IDENTIFIER The mandated SignedAttr field must include the object identifier for all those signed attributes required by this document as well as additional attributes required by this policy. The mandatedUnsignedAttr field must include the object identifier for all those unsigned attributes required by this document as well as additional attributes required by this policy. For example, if a signature time-stamp <see section 1.1) is required by the signer the object identifier for this attribute must be included. The mandatedCertificateRef identifies whether just the signer's certificate, or all the full certificate path must be provided by the signer. CertRefReq ::= ENUMERATED { signerOnly (1), -- Only reference to signer cert mandated fullpath (2) -- References for full cert path up to a trust point required } The mandatedCertificateInfo field identifies whether a signer's certificate, or all certificates in the certification path to the trust point must be provided by the signer in the certificates field of SignedData. CertInfoReq ::= ENUMERATED { none (0) , -- No mandatory requirements signerOnly (1) , -- Only reference to signer cert mandated fullpath (2) -- References for full cert path up to a -- trust point mandated } Ross, et al. Experimental [Page 10]
RFC 3125 Electronic Signature Policies September 2001 3.5.2 Verifier Rules The verifier rules identify: * The CMS unsigned attributes that must be present under this policy and must be added by the verifier if not added by the signer. VerifierRules ::= SEQUENCE { mandatedUnsignedAttr MandatedUnsignedAttr, signPolExtensions SignPolExtensions OPTIONAL } MandatedUnsignedAttr ::= CMSAttrs -- Mandated CMS unsigned attributed 3.6 Certificate and Revocation Requirement The SigningCertTrustCondition, TimestampTrustCondition and AttributeTrustCondition (defined in subsequent sub-sections) make use of two ASN1 structures which are defined below: CertificateTrustTrees and CertRevReq. 3.6.1 Certificate Requirements The certificateTrustTrees identifies a set of self signed certificates for the trust points used to start (or end) certificate path processing and the initial conditions for certificate path validation as defined RFC 2459 [7] section 4. This ASN1 structure is used to define policy for validating the signing certificate, the TSA's certificate and attribute certificates. CertificateTrustTrees ::= SEQUENCE OF CertificateTrustPoint CertificateTrustPoint ::= SEQUENCE { trustpoint Certificate, -- self-signed certificate pathLenConstraint [0] PathLenConstraint OPTIONAL, acceptablePolicySet [1] AcceptablePolicySet OPTIONAL, -- If not present "any policy" nameConstraints [2] NameConstraints OPTIONAL, policyConstraints [3] PolicyConstraints OPTIONAL } The trustPoint field gives the self signed certificate for the CA that is used as the trust point for the start of certificate path processing. Ross, et al. Experimental [Page 11]
RFC 3125 Electronic Signature Policies September 2001 The pathLenConstraint field gives the maximum number of CA certificates that may be in a certification path following the trustpoint. A value of zero indicates that only the given trustpoint certificate and an end-entity certificate may be used. If present, the pathLenConstraint field must be greater than or equal to zero. Where pathLenConstraint is not present, there is no limit to the allowed length of the certification path. PathLenConstraint ::= INTEGER (0..MAX) The acceptablePolicySet field identifies the initial set of certificate policies, any of which are acceptable under the signature policy. AcceptablePolicySet ::= SEQUENCE OF CertPolicyId CertPolicyId ::= OBJECT IDENTIFIER The nameConstraints field indicates a name space within which all subject names in subsequent certificates in a certification path must be located. Restrictions may apply to the subject distinguished name or subject alternative names. Restrictions apply only when the specified name form is present. If no name of the type is in the certificate, the certificate is acceptable. Restrictions are defined in terms of permitted or excluded name subtrees. Any name matching a restriction in the excludedSubtrees field is invalid regardless of information appearing in the permittedSubtrees. NameConstraints ::= SEQUENCE { permittedSubtrees [0] GeneralSubtrees OPTIONAL, excludedSubtrees [1] GeneralSubtrees OPTIONAL } GeneralSubtrees ::= SEQUENCE SIZE (1..MAX) OF GeneralSubtree GeneralSubtree ::= SEQUENCE { base GeneralName, minimum [0] BaseDistance DEFAULT 0, maximum [1] BaseDistance OPTIONAL } BaseDistance ::= INTEGER (0..MAX) The policyConstraints extension constrains path processing in two ways. It can be used to prohibit policy mapping or require that each certificate in a path contain an acceptable policy identifier. The policyConstraints field, if present specifies requirement for explicit indication of the certificate policy and/or the constraints on policy mapping. Ross, et al. Experimental [Page 12]
RFC 3125 Electronic Signature Policies September 2001 PolicyConstraints ::= SEQUENCE { requireExplicitPolicy [0] SkipCerts OPTIONAL, inhibitPolicyMapping [1] SkipCerts OPTIONAL } SkipCerts ::= INTEGER (0..MAX) If the inhibitPolicyMapping field is present, the value indicates the number of additional certificates that may appear in the path (including the trustpoint's self certificate) before policy mapping is no longer permitted. For example, a value of one indicates that policy mapping may be processed in certificates issued by the subject of this certificate, but not in additional certificates in the path. If the requireExplicitPolicy field is present, subsequent certificates must include an acceptable policy identifier. The value of requireExplicitPolicy indicates the number of additional certificates that may appear in the path (including the trustpoint's self certificate) before an explicit policy is required. An acceptable policy identifier is the identifier of a policy required by the user of the certification path or the identifier of a policy which has been declared equivalent through policy mapping. 3.6.2 Revocation Requirements The RevocRequirements field specifies minimum requirements for revocation information, obtained through CRLs and/or OCSP responses, to be used in checking the revocation status of certificates. This ASN1 structure is used to define policy for validating the signing certificate, the TSA's certificate and attribute certificates. CertRevReq ::= SEQUENCE { endCertRevReq RevReq, caCerts [0] RevReq } Certificate revocation requirements are specified in terms of checks required on: * endCertRevReq: end certificates (i.e., the signers certificate, the attribute certificate or the time-stamping authority certificate). * caCerts: CA certificates. RevReq ::= SEQUENCE { enuRevReq EnuRevReq, exRevReq SignPolExtensions OPTIONAL} Ross, et al. Experimental [Page 13]
RFC 3125 Electronic Signature Policies September 2001 An authority certificate is certificate issued to an authority (e.g., either to a certification authority or to an attribute authority (AA)). A Time-Stamping Authority (TSA) is a trusted third party that creates time-stamp tokens in order to indicate that a datum existed at a particular point in time. See [TSP]. EnuRevReq ::= ENUMERATED { clrCheck (0), --Checks must be made against current CRLs -- (or authority revocation lists (ARL)) ocspCheck (1), -- The revocation status must be checked -- using the Online Certificate Status Protocol -- (OCSP),RFC 2450. bothCheck (2), -- Both CRL and OCSP checks must be carried out eitherCheck (3), -- At least one of CRL or OCSP checks must be -- carried out noCheck (4), -- no check is mandated other (5) -- Other mechanism as defined by signature policy -- extension } Revocation requirements are specified in terms of: * clrCheck: Checks must be made against current CRLs (or authority revocation lists); * ocspCheck: The revocation status must be checked using the Online Certificate Status Protocol (RFC 2450); * bothCheck: Both OCSP and CRL checks must be carried out; * eitherCheck: Either OCSP or CRL checks must be carried out; * noCheck: No check is mandated. 3.7 Signing Certificate Trust Conditions The SigningCertTrustCondition field identifies trust conditions for certificate path processing used to validate the signing certificate. SigningCertTrustCondition ::= SEQUENCE { signerTrustTrees CertificateTrustTrees, signerRevReq CertRevReq } Ross, et al. Experimental [Page 14]
RFC 3125 Electronic Signature Policies September 2001 3.8 Time-Stamp Trust Conditions The TimeStampTrustCondition field identifies trust conditions for certificate path processing used to authenticate the timstamping authority and constraints on the name of the time-stamping authority. This applies to the time-stamp that must be present in every ES-T. TimestampTrustCondition ::= SEQUENCE { ttsCertificateTrustTrees [0] CertificateTrustTrees OPTIONAL, ttsRevReq [1] CertRevReq OPTIONAL, ttsNameConstraints [2] NameConstraints OPTIONAL, cautionPeriod [3] DeltaTime OPTIONAL, signatureTimestampDelay [4] DeltaTime OPTIONAL } DeltaTime ::= SEQUENCE { deltaSeconds INTEGER, deltaMinutes INTEGER, deltaHours INTEGER, deltaDays INTEGER } If ttsCertificateTrustTrees is not present then the same rule as defined in certificateTrustCondition applies to certification of the time-stamping authorities public key. The tstrRevReq specifies minimum requirements for revocation information, obtained through CRLs and/or OCSP responses, to be used in checking the revocation status of the time-stamp that must be present in the ES-T. If ttsNameConstraints is not present then there are no additional naming constraints on the trusted time-stamping authority other than those implied by the ttsCertificateTrustTrees. The cautionPeriod field specifies a caution period after the signing time that it is mandated the verifier must wait to get high assurance of the validity of the signer's key and that any relevant revocation has been notified. The revocation status information forming the ES with Complete validation data must not be collected and used to validate the electronic signature until after this caution period. The signatureTimestampDelay field specifies a maximum acceptable time between the signing time and the time at which the signature time- stamp, as used to form the ES Time-Stamped, is created for the Ross, et al. Experimental [Page 15]
RFC 3125 Electronic Signature Policies September 2001 verifier. If the signature time-stamp is later that the time in the signing-time attribute by more than the value given in signatureTimestampDelay, the signature must be considered invalid. 3.9 Attribute Trust Conditions If the attributeTrustCondition field is not present then any certified attributes may not considered to be valid under this validation policy. The AttributeTrustCondition field is defined as follows: AttributeTrustCondition ::= SEQUENCE { attributeMandated BOOLEAN, -- Attribute must be present howCertAttribute HowCertAttribute, attrCertificateTrustTrees [0] CertificateTrustTrees OPTIONAL, attrRevReq [1] CertRevReq OPTIONAL, attributeConstraints [2] AttributeConstraints OPTIONAL } If attributeMandated is true then an attribute, certified within the following constraints, must be present. If false, then the signature is still valid if no attribute is specified. The howCertAttribute field specifies whether attributes uncertified attributes "claimed" by the signer, or certified attributes (i.e., Attribute Certificates) or either using the signer attributes attribute defined in [ES-FORMATS] section 3.12.3. HowCertAttribute ::= ENUMERATED { claimedAttribute (0), certifiedAttribtes (1), either (2) } The attrCertificateTrustTrees specifies certificate path conditions for any attribute certificate. If not present the same rules apply as in certificateTrustCondition. The attrRevReq specifies minimum requirements for revocation information, obtained through CRLs and/or OCSP responses, to be used in checking the revocation status of Attribute Certificates, if any are present. If the attributeConstraints field is not present then there are no constraints on the attributes that may be validated under this policy. The attributeConstraints field is defined as follows: Ross, et al. Experimental [Page 16]
RFC 3125 Electronic Signature Policies September 2001 AttributeConstraints ::= SEQUENCE { attributeTypeConstarints [0] AttributeTypeConstraints OPTIONAL, attributeValueConstarints [1] AttributeValueConstraints OPTIONAL } If present, the attributeTypeConstarints field specifies the attribute types which are considered valid under the signature policy. Any value for that attribute is considered valid. AttributeTypeConstraints ::= SEQUENCE OF AttributeType If present, the attributeTypeConstraints field specifies the specific attribute values which are considered valid under the signature policy. AttributeValueConstraints ::= SEQUENCE OF AttributeTypeAndValue 3.10 Algorithm Constraints The algorithmConstrains fields, if present, identifies the signing algorithms (hash, public key cryptography, combined hash and public key cryptography) that may be used for specific purposes and any minimum length. If this field is not present then the policy applies no constraints. AlgorithmConstraintSet ::= SEQUENCE { -- Algorithm constrains on: signerAlgorithmConstraints [0] AlgorithmConstraints OPTIONAL, -- signer eeCertAlgorithmConstraints [1] AlgorithmConstraints OPTIONAL, -- issuer of end entity certs. caCertAlgorithmConstraints [2] AlgorithmConstraints OPTIONAL, -- issuer of CA certificates aaCertAlgorithmConstraints [3] AlgorithmConstraints OPTIONAL, -- Attribute Authority tsaCertAlgorithmConstraints [4] AlgorithmConstraints OPTIONAL -- Time-Stamping Authority } AlgorithmConstraints ::= SEQUENCE OF AlgAndLength AlgAndLength ::= SEQUENCE { algID OBJECT IDENTIFIER, minKeyLength INTEGER OPTIONAL, -- Minimum key length in bits other SignPolExtensions OPTIONAL } Ross, et al. Experimental [Page 17]
RFC 3125 Electronic Signature Policies September 2001 An Attribute Authority (AA)is authority which assigns privileges by issuing attribute certificates 3.11 Signature Policy Extensions Additional signature policy rules may be added to: * the overall signature policy structure, as defined in section 3.1; * the signature validation policy structure, as defined in section 3.2; * the common rules, as defined in section 3.3; * the commitment rules, as defined in section 3.4; * the signer rules, as defined in section 3.5.1; * the verifier rules, as defined in section 3.5.2; * the revocation requirements in section 3.6.2; * the algorithm constraints in section 3.10. These extensions to the signature policy rules must be defined using an ASN.1 syntax with an associated object identifier carried in the SignPolExtn as defined below: SignPolExtensions ::= SEQUENCE OF SignPolExtn SignPolExtn ::= SEQUENCE { extnID OBJECT IDENTIFIER, extnValue OCTET STRING } The extnID field must contain the object identifier for the extension. The extnValue field must contain the DER (see ITU-T Recommendation X.690 [4]) encoded value of the extension. The definition of an extension, as identified by extnID must include a definition of the syntax and semantics of the extension. 4. Security Considerations 4.1 Protection of Private Key The security of the electronic signature mechanism defined in this document depends on the privacy of the signer's private key. Implementations must take steps to ensure that private keys cannot be compromised. 4.2 Choice of Algorithms Implementers should be aware that cryptographic algorithms become weaker with time. As new cryptoanalysis techniques are developed and computing performance improves, the work factor to break a particular Ross, et al. Experimental [Page 18]
RFC 3125 Electronic Signature Policies September 2001 cryptographic algorithm will reduce. Therefore, cryptographic algorithm implementations should be modular allowing new algorithms to be readily inserted. That is, implementers should be prepared for the set of mandatory to implement algorithms to change over time. 5. Conformance Requirements Signer and verifier systems shall be able to process an electronic signature in accordance with the specification of the signature policy signature policy referenced identifiable by an Object Identifier, see section 3. 6. References [TS101733] ETSI Standard TS 101 733 V.1.2.2 (2000-12) Electronic Signature Formats. Note: copies of ETSI TS 101 733 can be freely download from the ETSI web site www.etsi.org. [ES-FORMATS] Pinkas, D., Ross, J. and N. Pope, "Electronic Signature Formats for Long Term Electronic Signatures", RFC 3126, June 2001. [TSP] Adams, C, Pinkas, D., Zuccherato, R. and P. Cain, "Internet X.509 Public Key Infrastructure Time-Stamp Protocol (TSP)", RFC 3161, August 2001. [OCSP] Myers, M., Ankney, R., Malpani, R., Galperin, S. and C. Adams, "On-line Status Certificate Protocol", RFC 2560, June 1999. [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, March 1997. [ESS] Hoffman, P., "Enhanced Security Services for S/MIME", RFC 2634, June 1999. [CMS] Housley, R., "Cryptographic Message Syntax", RFC 2630, June 1999. [RFC2459] Housley, R., Ford, W., Polk, W. and D. Solo, "Internet X.509 Public Key Infrastructure, Certificate and CRL Profile," RFC 2459, January 1999. [PKCS9] RSA Laboratories, "The Public-Key Cryptography Standards (PKCS)", RSA Data Security Inc., Redwood City, California, November 1993 Release. Ross, et al. Experimental [Page 19]
RFC 3125 Electronic Signature Policies September 2001 [ISONR] ISO/IEC 10181-5: Security Frameworks in Open Systems. Non-Repudiation Framework. April 1997. 7. Authors' Addresses This Experimental RFC has been produced in ETSI TC-SEC. ETSI F-06921 Sophia Antipolis, Cedex - FRANCE 650 Route des Lucioles - Sophia Antipolis Valbonne - FranceTel: +33 4 92 94 42 00 Fax: +33 4 93 65 47 16 secretariat@etsi.fr http://www.etsi.org Contact Point Harri Rasilainen ETSI 650 Route des Lucioles F-06921 Sophia Antipolis Cedex FRANCE EMail: harri.rasilainen@etsi.fr John Ross Security & Standards 192 Moulsham Street Chelmsford, Essex CM2 0LG United Kingdom EMail: ross@secstan.com Denis Pinkas Integris, Bull. 68, Route de Versailles 78434 Louveciennes CEDEX FRANCE EMail: Denis.Pinkas@bull.net Nick Pope Security & Standards 192 Moulsham Street Chelmsford, Essex CM2 0LG United Kingdom EMail: pope@secstan.com Ross, et al. Experimental [Page 20]
RFC 3125 Electronic Signature Policies September 2001 Annex A (normative): ASN.1 Definitions This annex provides the reference definition of the ASN.1 syntax signature policies definitions for new syntax defined in this document. A.1 Definitions Using X.208 (1988) ASN.1 Syntax NOTE: The ASN.1 Module defined in section A.1 has precedence over that defined in Annex A-2 in the case of any conflict. ETS-ElectronicSignaturePolicies-88syntax { iso(1) member-body(2) us(840) rsadsi(113549) pkcs(1) pkcs-9(9) smime(16) id-mod(0) 7} DEFINITIONS EXPLICIT TAGS ::= BEGIN -- EXPORTS All IMPORTS -- Internet X.509 Public Key Infrastructure - Certificate and CRL Profile: RFC 2560 Certificate, AlgorithmIdentifier, CertificateList, Name, GeneralNames, GeneralName, DirectoryString,Attribute, AttributeTypeAndValue, AttributeType, AttributeValue, PolicyInformation, BMPString, UTF8String FROM PKIX1Explicit88 {iso(1) identified-organization(3) dod(6) internet(1) security(5) mechanisms(5) pkix(7) id-mod(0) id-pkix1-explicit-88(1)} ; -- Signature Policy Specification -- ============================== SignaturePolicy ::= SEQUENCE { signPolicyHashAlg AlgorithmIdentifier, signPolicyInfo SignPolicyInfo, signPolicyHash SignPolicyHash OPTIONAL } SignPolicyHash ::= OCTET STRING SignPolicyInfo ::= SEQUENCE { signPolicyIdentifier SignPolicyId, dateOfIssue GeneralizedTime, policyIssuerName PolicyIssuerName, Ross, et al. Experimental [Page 21]
RFC 3125 Electronic Signature Policies September 2001 fieldOfApplication FieldOfApplication, signatureValidationPolicy SignatureValidationPolicy, signPolExtensions SignPolExtensions OPTIONAL } PolicyIssuerName ::= GeneralNames FieldOfApplication ::= DirectoryString SignatureValidationPolicy ::= SEQUENCE { signingPeriod SigningPeriod, commonRules CommonRules, commitmentRules CommitmentRules, signPolExtensions SignPolExtensions OPTIONAL } SigningPeriod ::= SEQUENCE { notBefore GeneralizedTime, notAfter GeneralizedTime OPTIONAL } CommonRules ::= SEQUENCE { signerAndVeriferRules [0] SignerAndVerifierRules OPTIONAL, signingCertTrustCondition [1] SigningCertTrustCondition OPTIONAL, timeStampTrustCondition [2] TimestampTrustCondition OPTIONAL, attributeTrustCondition [3] AttributeTrustCondition OPTIONAL, algorithmConstraintSet [4] AlgorithmConstraintSet OPTIONAL, signPolExtensions [5] SignPolExtensions OPTIONAL } CommitmentRules ::= SEQUENCE OF CommitmentRule CommitmentRule ::= SEQUENCE { selCommitmentTypes SelectedCommitmentTypes, signerAndVeriferRules [0] SignerAndVerifierRules OPTIONAL, signingCertTrustCondition [1] SigningCertTrustCondition OPTIONAL, timeStampTrustCondition [2] TimestampTrustCondition OPTIONAL, Ross, et al. Experimental [Page 22]
RFC 3125 Electronic Signature Policies September 2001 attributeTrustCondition [3] AttributeTrustCondition OPTIONAL, algorithmConstraintSet [4] AlgorithmConstraintSet OPTIONAL, signPolExtensions [5] SignPolExtensions OPTIONAL } SelectedCommitmentTypes ::= SEQUENCE OF CHOICE { empty NULL, recognizedCommitmentType CommitmentType } CommitmentType ::= SEQUENCE { identifier CommitmentTypeIdentifier, fieldOfApplication [0] FieldOfApplication OPTIONAL, semantics [1] DirectoryString OPTIONAL } SignerAndVerifierRules ::= SEQUENCE { signerRules SignerRules, verifierRules VerifierRules } SignerRules ::= SEQUENCE { externalSignedData BOOLEAN OPTIONAL, -- True if signed data is external to CMS structure -- False if signed data part of CMS structure -- not present if either allowed mandatedSignedAttr CMSAttrs, -- Mandated CMS signed attributes mandatedUnsignedAttr CMSAttrs, -- Mandated CMS unsigned attributed mandatedCertificateRef [0] CertRefReq DEFAULT signerOnly, -- Mandated Certificate Reference mandatedCertificateInfo [1] CertInfoReq DEFAULT none, -- Mandated Certificate Info signPolExtensions [2] SignPolExtensions OPTIONAL} CMSAttrs ::= SEQUENCE OF OBJECT IDENTIFIER CertRefReq ::= ENUMERATED { signerOnly (1), -- Only reference to signer cert mandated fullPath (2) -- References for full cert path up to a trust point required } CertInfoReq ::= ENUMERATED { Ross, et al. Experimental [Page 23]
RFC 3125 Electronic Signature Policies September 2001 none (0), -- No mandatory requirements signerOnly (1), -- Only reference to signer cert mandated fullPath (2) -- References for full cert path up to a trust point mandated } VerifierRules ::= SEQUENCE { mandatedUnsignedAttr MandatedUnsignedAttr, signPolExtensions SignPolExtensions OPTIONAL } MandatedUnsignedAttr ::= CMSAttrs -- Mandated CMS unsigned attributed CertificateTrustTrees ::= SEQUENCE OF CertificateTrustPoint CertificateTrustPoint ::= SEQUENCE { trustpoint Certificate, -- self-signed certificate pathLenConstraint [0] PathLenConstraint OPTIONAL, acceptablePolicySet [1] AcceptablePolicySet OPTIONAL, -- If not present "any policy" nameConstraints [2] NameConstraints OPTIONAL, policyConstraints [3] PolicyConstraints OPTIONAL } PathLenConstraint ::= INTEGER (0..MAX) AcceptablePolicySet ::= SEQUENCE OF CertPolicyId CertPolicyId ::= OBJECT IDENTIFIER NameConstraints ::= SEQUENCE { permittedSubtrees [0] GeneralSubtrees OPTIONAL, excludedSubtrees [1] GeneralSubtrees OPTIONAL } GeneralSubtrees ::= SEQUENCE SIZE (1..MAX) OF GeneralSubtree GeneralSubtree ::= SEQUENCE { base GeneralName, minimum [0] BaseDistance DEFAULT 0, maximum [1] BaseDistance OPTIONAL } BaseDistance ::= INTEGER (0..MAX) PolicyConstraints ::= SEQUENCE { requireExplicitPolicy [0] SkipCerts OPTIONAL, Ross, et al. Experimental [Page 24]
RFC 3125 Electronic Signature Policies September 2001 inhibitPolicyMapping [1] SkipCerts OPTIONAL } SkipCerts ::= INTEGER (0..MAX) CertRevReq ::= SEQUENCE { endCertRevReq RevReq, caCerts [0] RevReq } RevReq ::= SEQUENCE { enuRevReq EnuRevReq, exRevReq SignPolExtensions OPTIONAL} EnuRevReq ::= ENUMERATED { clrCheck (0), --Checks must be made against current CRLs -- (or authority revocation lists) ocspCheck (1), -- The revocation status must be checked -- using the Online Certificate Status Protocol (RFC 2450) bothCheck (2), -- Both CRL and OCSP checks must be carried out eitherCheck (3), -- At least one of CRL or OCSP checks must be carried out noCheck (4), -- no check is mandated other (5) -- Other mechanism as defined by signature policy extension } SigningCertTrustCondition ::= SEQUENCE { signerTrustTrees CertificateTrustTrees, signerRevReq CertRevReq } TimestampTrustCondition ::= SEQUENCE { ttsCertificateTrustTrees [0] CertificateTrustTrees OPTIONAL, ttsRevReq [1] CertRevReq OPTIONAL, ttsNameConstraints [2] NameConstraints OPTIONAL, cautionPeriod [3] DeltaTime OPTIONAL, signatureTimestampDelay [4] DeltaTime OPTIONAL } DeltaTime ::= SEQUENCE { deltaSeconds INTEGER, deltaMinutes INTEGER, Ross, et al. Experimental [Page 25]
RFC 3125 Electronic Signature Policies September 2001 deltaHours INTEGER, deltaDays INTEGER } AttributeTrustCondition ::= SEQUENCE { attributeMandated BOOLEAN, -- Attribute must be present howCertAttribute HowCertAttribute, attrCertificateTrustTrees [0] CertificateTrustTrees OPTIONAL, attrRevReq [1] CertRevReq OPTIONAL, attributeConstraints [2] AttributeConstraints OPTIONAL } HowCertAttribute ::= ENUMERATED { claimedAttribute (0), certifiedAttribtes (1), either (2) } AttributeConstraints ::= SEQUENCE { attributeTypeConstarints [0] AttributeTypeConstraints OPTIONAL, attributeValueConstarints [1] AttributeValueConstraints OPTIONAL } AttributeTypeConstraints ::= SEQUENCE OF AttributeType AttributeValueConstraints ::= SEQUENCE OF AttributeTypeAndValue AlgorithmConstraintSet ::= SEQUENCE { -- Algorithm constrains on: signerAlgorithmConstraints [0] AlgorithmConstraints OPTIONAL, -- signer eeCertAlgorithmConstraints [1] AlgorithmConstraints OPTIONAL, -- issuer of end entity certs. caCertAlgorithmConstraints [2] AlgorithmConstraints OPTIONAL, -- issuer of CA certificates aaCertAlgorithmConstraints [3] AlgorithmConstraints OPTIONAL, -- Attribute Authority tsaCertAlgorithmConstraints [4] AlgorithmConstraints OPTIONAL -- Time-Stamping Authority } AlgorithmConstraints ::= SEQUENCE OF AlgAndLength AlgAndLength ::= SEQUENCE { algID OBJECT IDENTIFIER, minKeyLength INTEGER OPTIONAL, -- Minimum key length in bits other SignPolExtensions OPTIONAL Ross, et al. Experimental [Page 26]
RFC 3125 Electronic Signature Policies September 2001 } SignPolExtensions ::= SEQUENCE OF SignPolExtn SignPolExtn ::= SEQUENCE { extnID OBJECT IDENTIFIER, extnValue OCTET STRING } END -- ETS-ElectronicSignaturePolicies-88syntax -- A.2 Definitions Using X.680 1997 ASN.1 Syntax NOTE: The ASN.1 module defined in section A.1 has precedence over that defined in section A.2 in the case of any conflict. ETS-ElectronicSignaturePolicies-97Syntax { iso(1) member-body(2) us(840) rsadsi(113549) pkcs(1) pkcs-9(9) smime(16) id-mod(0) 8} DEFINITIONS EXPLICIT TAGS ::= BEGIN -- EXPORTS All - IMPORTS -- Internet X.509 Public Key Infrastructure -- Certificate and CRL Profile: RFC 2560 Certificate, AlgorithmIdentifier, CertificateList, Name, GeneralNames, GeneralName, DirectoryString, Attribute, AttributeTypeAndValue, AttributeType, AttributeValue, PolicyInformation FROM PKIX1Explicit93 {iso(1) identified-organization(3) dod(6) internet(1) security(5) mechanisms(5) pkix(7) id-mod(0) nid-pkix1-explicit-88(1)} ; -- S/MIME Object Identifier arcs used in the present document -- ================================================================== -- S/MIME OID arc used in the present document -- id-smime OBJECT IDENTIFIER ::= { iso(1) member-body(2) -- us(840) rsadsi(113549) pkcs(1) pkcs-9(9) 16 } -- S/MIME Arcs -- id-mod OBJECT IDENTIFIER ::= { id-smime 0 } -- modules Ross, et al. Experimental [Page 27]
RFC 3125 Electronic Signature Policies September 2001 -- id-ct OBJECT IDENTIFIER ::= { id-smime 1 } -- content types -- id-aa OBJECT IDENTIFIER ::= { id-smime 2 } -- attributes -- id-spq OBJECT IDENTIFIER ::= { id-smime 5 } -- signature policy qualifier -- id-cti OBJECT IDENTIFIER ::= { id-smime 6 } -- commitment type identifier -- Signature Policy Specification -- ============================== SignaturePolicy ::= SEQUENCE { signPolicyHashAlg AlgorithmIdentifier, signPolicyInfo SignPolicyInfo, signPolicyHash SignPolicyHash OPTIONAL } SignPolicyHash ::= OCTET STRING SignPolicyInfo ::= SEQUENCE { signPolicyIdentifier SignPolicyId, dateOfIssue GeneralizedTime, policyIssuerName PolicyIssuerName, fieldOfApplication FieldOfApplication, signatureValidationPolicy SignatureValidationPolicy, signPolExtensions SignPolExtensions OPTIONAL } SignPolicyId ::= OBJECT IDENTIFIER PolicyIssuerName ::= GeneralNames FieldOfApplication ::= DirectoryString SignatureValidationPolicy ::= SEQUENCE { signingPeriod SigningPeriod, commonRules CommonRules, commitmentRules CommitmentRules, signPolExtensions SignPolExtensions OPTIONAL } SigningPeriod ::= SEQUENCE { notBefore GeneralizedTime, notAfter GeneralizedTime OPTIONAL } CommonRules ::= SEQUENCE { signerAndVeriferRules [0] SignerAndVerifierRules OPTIONAL, Ross, et al. Experimental [Page 28]
RFC 3125 Electronic Signature Policies September 2001 signingCertTrustCondition [1] SigningCertTrustCondition OPTIONAL, timeStampTrustCondition [2] TimestampTrustCondition OPTIONAL, attributeTrustCondition [3] AttributeTrustCondition OPTIONAL, algorithmConstraintSet [4] AlgorithmConstraintSet OPTIONAL, signPolExtensions [5] SignPolExtensions OPTIONAL } CommitmentRules ::= SEQUENCE OF CommitmentRule CommitmentRule ::= SEQUENCE { selCommitmentTypes SelectedCommitmentTypes, signerAndVeriferRules [0] SignerAndVerifierRules OPTIONAL, signingCertTrustCondition [1] SigningCertTrustCondition OPTIONAL, timeStampTrustCondition [2] TimestampTrustCondition OPTIONAL, attributeTrustCondition [3] AttributeTrustCondition OPTIONAL, algorithmConstraintSet [4] AlgorithmConstraintSet OPTIONAL, signPolExtensions [5] SignPolExtensions OPTIONAL } SelectedCommitmentTypes ::= SEQUENCE OF CHOICE { empty NULL, recognizedCommitmentType CommitmentType } CommitmentType ::= SEQUENCE { identifier CommitmentTypeIdentifier, fieldOfApplication [0] FieldOfApplication OPTIONAL, semantics [1] DirectoryString OPTIONAL } SignerAndVerifierRules ::= SEQUENCE { signerRules SignerRules, verifierRules VerifierRules } SignerRules ::= SEQUENCE { externalSignedData BOOLEAN OPTIONAL, -- True if signed data is external to CMS structure -- False if signed data part of CMS structure -- not present if either allowed Ross, et al. Experimental [Page 29]
RFC 3125 Electronic Signature Policies September 2001 mandatedSignedAttr CMSAttrs, -- Mandated CMS signed attributes mandatedUnsignedAttr CMSAttrs, -- Mandated CMS unsigned attributed mandatedCertificateRef [0] CertRefReq DEFAULT signerOnly, -- Mandated Certificate Reference mandatedCertificateInfo [1] CertInfoReq DEFAULT none, -- Mandated Certificate Info signPolExtensions [2] SignPolExtensions OPTIONAL } CMSAttrs ::= SEQUENCE OF OBJECT IDENTIFIER CertRefReq ::= ENUMERATED { signerOnly (1), -- Only reference to signer cert mandated fullPath (2) -- References for full cert path up to a trust -- point required } CertInfoReq ::= ENUMERATED { none (0) , -- No mandatory requirements signerOnly (1) , -- Only reference to signer cert mandated fullPath (2) -- References for full cert path up to a -- trust point mandated } VerifierRules ::= SEQUENCE { mandatedUnsignedAttr MandatedUnsignedAttr, signPolExtensions SignPolExtensions OPTIONAL } MandatedUnsignedAttr ::= CMSAttrs -- Mandated CMS unsigned attributed CertificateTrustTrees ::= SEQUENCE OF CertificateTrustPoint CertificateTrustPoint ::= SEQUENCE { trustpoint Certificate, -- self-signed certificate pathLenConstraint [0] PathLenConstraint OPTIONAL, acceptablePolicySet [1] AcceptablePolicySet OPTIONAL, -- If not present "any policy" nameConstraints [2] NameConstraints OPTIONAL, policyConstraints [3] PolicyConstraints OPTIONAL } Ross, et al. Experimental [Page 30]
RFC 3125 Electronic Signature Policies September 2001 PathLenConstraint ::= INTEGER (0..MAX) AcceptablePolicySet ::= SEQUENCE OF CertPolicyId CertPolicyId ::= OBJECT IDENTIFIER NameConstraints ::= SEQUENCE { permittedSubtrees [0] GeneralSubtrees OPTIONAL, excludedSubtrees [1] GeneralSubtrees OPTIONAL } GeneralSubtrees ::= SEQUENCE SIZE (1..MAX) OF GeneralSubtree GeneralSubtree ::= SEQUENCE { base GeneralName, minimum [0] BaseDistance DEFAULT 0, maximum [1] BaseDistance OPTIONAL } BaseDistance ::= INTEGER (0..MAX) PolicyConstraints ::= SEQUENCE { requireExplicitPolicy [0] SkipCerts OPTIONAL, inhibitPolicyMapping [1] SkipCerts OPTIONAL } SkipCerts ::= INTEGER (0..MAX) CertRevReq ::= SEQUENCE { endCertRevReq RevReq, caCerts [0] RevReq } RevReq ::= SEQUENCE { enuRevReq EnuRevReq, exRevReq SignPolExtensions OPTIONAL} EnuRevReq ::= ENUMERATED { clrCheck (0), -- Checks must be made against current CRLs -- (or authority revocation lists) ocspCheck (1), -- The revocation status must be checked using -- the Online Certificate Status Protocol (RFC 2450) bothCheck (2), -- Both CRL and OCSP checks must be carried out eitherCheck (3), -- At least one of CRL or OCSP checks must be -- carried out noCheck (4), -- no check is mandated Ross, et al. Experimental [Page 31]
RFC 3125 Electronic Signature Policies September 2001 other (5) -- Other mechanism as defined by signature policy -- extension } SigningCertTrustCondition ::= SEQUENCE { signerTrustTrees CertificateTrustTrees, signerRevReq CertRevReq } TimestampTrustCondition ::= SEQUENCE { ttsCertificateTrustTrees [0] CertificateTrustTrees OPTIONAL, ttsRevReq [1] CertRevReq OPTIONAL, ttsNameConstraints [2] NameConstraints OPTIONAL, cautionPeriod [3] DeltaTime OPTIONAL, signatureTimestampDelay [4] DeltaTime OPTIONAL } DeltaTime ::= SEQUENCE { deltaSeconds INTEGER, deltaMinutes INTEGER, deltaHours INTEGER, deltaDays INTEGER } AttributeTrustCondition ::= SEQUENCE { attributeMandated BOOLEAN, -- Attribute must be present howCertAttribute HowCertAttribute, attrCertificateTrustTrees [0] CertificateTrustTrees OPTIONAL, attrRevReq [1] CertRevReq OPTIONAL, attributeConstraints [2] AttributeConstraints OPTIONAL } HowCertAttribute ::= ENUMERATED { claimedAttribute (0), certifiedAttribtes (1), either (2) } AttributeConstraints ::= SEQUENCE { attributeTypeConstarints [0] AttributeTypeConstraints OPTIONAL, attributeValueConstarints [1] AttributeValueConstraints OPTIONAL } Ross, et al. Experimental [Page 32]
RFC 3125 Electronic Signature Policies September 2001 AttributeTypeConstraints ::= SEQUENCE OF AttributeType AttributeValueConstraints ::= SEQUENCE OF AttributeTypeAndValue AlgorithmConstraintSet ::= SEQUENCE { -- Algorithm constrains on: signerAlgorithmConstraints [0] AlgorithmConstraints OPTIONAL, -- signer eeCertAlgorithmConstraints [1] AlgorithmConstraints OPTIONAL, -- issuer of end entity certs. caCertAlgorithmConstraints [2] AlgorithmConstraints OPTIONAL, -- issuer of CA certificates aaCertAlgorithmConstraints [3] AlgorithmConstraints OPTIONAL, -- Attribute Authority tsaCertAlgorithmConstraints [4] AlgorithmConstraints OPTIONAL -- Time-Stamping Authority } AlgorithmConstraints ::= SEQUENCE OF AlgAndLength AlgAndLength ::= SEQUENCE { algID OBJECT IDENTIFIER, minKeyLength INTEGER OPTIONAL, -- Minimum key length in bits other SignPolExtensions OPTIONAL } SignPolExtensions ::= SEQUENCE OF SignPolExtn SignPolExtn ::= SEQUENCE { extnID OBJECT IDENTIFIER, extnValue OCTET STRING } END -- ETS-ElectronicPolicies-97Syntax Ross, et al. Experimental [Page 33]
RFC 3125 Electronic Signature Policies September 2001 Annex B (informative): B.1 Signature Policy and Signature Validation Policy The definition of electronic signature mentions: "a commitment has been explicitly endorsed under a "Signature Policy", at a given time, by a signer under an identifier, e.g., a name or a pseudonym, and optionally a role." Electronic signatures are commonly applied within the context of a legal or contractual framework. This establishes the requirements on the electronic signatures and any special semantics (e.g., agreement, intent). These requirements may be defined in very general abstract terms or in terms of detailed rules. The specific semantics associated with an electronic signature implied by a legal or contractual framework are outside the scope of this document. If the signature policy is recognized, within the legal/contractual context, as providing commitment, then the signer explicitly agrees with terms and conditions which are implicitly or explicitly part of the signed data. When two independent parties want to evaluate an electronic signature, it is fundamental that they get the same result. It is therefore important that the conditions agreed by the signer at the time of signing are indicated to the verifier and any arbitrator. An aspect that enables this to be known by all parties is the signature policy. The technical implications of the signature policy on the electronic signature with all the validation data are called the "Signature Validation Policy". The signature validation policy specifies the rules used to validate the signature. This document does not mandate the form and encoding of the specification of the signature policy. However, for a given signature policy there must be one definitive form that has a unique binary encoded value. This document includes, as an option, a formal structure for signature validation policy based on the use of Abstract Syntax Notation 1 (ASN.1). Given the specification of the signature policy and its hash value an implementation of a verification process must obey the rules defined in the specification. This document places no restriction on how it should be implemented. Provide the implementation conforms to the conformance requirements as define in section 5 implementation options include: Ross, et al. Experimental [Page 34]
RFC 3125 Electronic Signature Policies September 2001 A validation process that supports a specific signature policy as identified by the signature policy OID. Such an implementation should conform to a human readable description provided all the processing rules of the signature policy are clearly defined. However, if additional policies need to be supported, then such an implementation would need to be customized for each additional policy. This type of implementation may be simpler to implement initially, but can be difficult to enhance to support numerous additional signature policies. A validation process that is dynamically programmable and able to adapt its validation rules in accordance with a description of the signature policy provided in a computer-processable language. This present document defines such a policy using an ASN.1 structure (see 6.1). This type of implementation could support multiple signature policies without being modified every time, provided all the validation rules specified as part of the signature policy are known by the implementation. (i.e., only requires modification if there are additional rules specified). The precise content of a signature policy is not mandated by the current document. However, a signature policy must be sufficiently definitive to avoid any ambiguity as to its implementation requirements. It must be absolutely clear under which conditions an electronic signature should be accepted. For this reason, it should contain the following information: * General information about the signature policy which includes: - a unique identifier of the policy; - the name of the issuer of the policy; - the date the policy was issued; - the field of application of the policy. * The signature verification policy which includes: - the signing period, - a list of recognized commitment types; - rules for Use of Certification Authorities; - rules for Use of Revocation Status Information; - rules for Use of Roles; - rules for use of Time-Stamping and Timing; - signature verification data to be provided by the signer/collected by verifier; - any constraints on signature algorithms and key lengths. * Other signature policy rules required to meet the objectives of the signature. Variations of the validation policy rules may apply to different commitment types. Ross, et al. Experimental [Page 35]
RFC 3125 Electronic Signature Policies September 2001 B.2 Identification of Signature Policy When data is signed the signer indicates the signature policy applicable to that electronic signature by including an object identifier for the signature policy with the signature. The signer and verifier must apply the rules specified by the identified policy. In addition to the identifier of the signature policy the signer must include the hash of the signature policy, so it can be verified that the policy selected by the signer is the identical to the one being used the verifier. A signature policy may be qualified by additional information. This can includes: * A URL where a copy of the Signature Policy may be obtained; * A user notice that should be displayed when the signature is verified; If no signature policy is identified then the signature may be assumed to have been generated/verified without any policy constraints, and hence may be given no specific legal or contractual significance through the context of a signature policy. A "Signature Policy" will be identifiable by an OID (Object Identifier) and verifiable using a hash of the signature policy. B.3 General Signature Policy Information General information should be recorded about the signature policy along with the definition of the rules which form the signature policy as described in subsequent subsections. This should include: * Policy Object Identifier: The "Signature Policy" will be identifiable by an OID (Object Identifier) whose last component (i.e., right most) is an integer that is specific to a particular version issued on the given date. * Date of issue: When the "Signature Policy" was issued. * Signature Policy Issuer name: An identifier for the body responsible for issuing the Signature Policy. This may be used by the signer or verifying in deciding if a policy is to be trusted, in which case the signer/verifier must authenticate the origin of the signature policy as coming from the identified issuer. * Signing period: The start time and date, optionally with an end time and date, for the period over which the signature policy may be used to generate electronic signatures. Ross, et al. Experimental [Page 36]
RFC 3125 Electronic Signature Policies September 2001 * Field of application: This defines in general terms the general legal/contract/application contexts in which the signature policy is to be used and the specific purposes for which the electronic signature is to be applied. B.4 Recognized Commitment Types The signature validation policy may recognize one or more types of commitment as being supported by electronic signatures produced under the security policy. If an electronic signature does not contain a recognized commitment type then the semantics of the electronic signature is dependent on the data being signed and the context in which it is being used. Only recognized commitment types are allowed in an electronic signature. The definition of a commitment type includes: * the object identifier for the commitment; * the contractual/legal/application context in which the signature may be used (e.g., submission of messages); * a description of the support provided within the terms of the context (e.g., proof that the identified source submitted the message if the signature is created when message submission is initiated). The definition of a commitment type can be registered: * as part of the validation policy; * as part of the application/contract/legal environment; * as part of generic register of definitions. The legal/contractual context will determine the rules applied to the signature, as defined by the signature policy and its recognized commitment types, make it fit for purpose intended. B.5 Rules for Use of Certification Authorities The certificate validation process of the verifier, and hence the certificates that may be used by the signer for a valid electronic signature, may be constrained by the combination of the trust point and certificate path constraints in the signature validation policy. Ross, et al. Experimental [Page 37]
RFC 3125 Electronic Signature Policies September 2001 B.5.1 Trust Points The signature validation policy defines the certification authority trust points that are to be used for signature verification. Several trust points may be specified under one signature policy. Specific trust points may be specified for a particular type of commitment defined under the signature policy. For a signature to be valid a certification path must exists between the Certification Authority that has granted the certificate selected by the signer (i.e., the used user-certificate) and one of the trust point of the "Signature Validation Policy". B.5.2 Certification Path There may be constraints on the use of certificates issued by one or more CA(s) in the certificate chain and trust points. The two prime constraints are certificate policy constraints and naming constraints: * Certificate policy constraints limit the certification chain between the user certificate and the certificate of the trusted point to a given set of certificate policies, or equivalents identified through certificate policy mapping. * The naming constraints limit the forms of names that the CA is allowed to certify. Name constraints are particularly important when a "Signature policy" identifies more than one trust point. In this case, a certificate of a particular trusted point may only be used to verify signatures from users with names permitted under the name constraint. Certificate Authorities may be organized in a tree structure, this tree structure may represent the trust relationship between various CA(s) and the users CA. Alternatively, a mesh relationship may exist where a combination of tree and peer cross-certificates may be used. The requirement of the certificate path in this document is that it provides the trust relationship between all the CAs and the signers user certificate. The starting point from a verification point of view, is the "trust point". A trust point is usually a CA that publishes self-certified certificates, is the starting point from which the verifier verifies the certificate chain. Naming constraints may apply from the trust point, in which case they apply throughout the set of certificates that make up the certificate path down to the signer's user certificate. Policy constraints can be easier to process but to be effective require the presence of a certificate policy identifier in the certificates used in a certification path. Ross, et al. Experimental [Page 38]
RFC 3125 Electronic Signature Policies September 2001 Certificate path processing, thus generally starts with one of the trust point from the signature policy and ends with the user certificate. The certificate path processing procedures defined in RFC 2459 section 6 identifies the following initial parameters that are selected by the verifier in certificate path processing: * acceptable certificate policies; * naming constraints in terms of constrained and excluded naming subtree; * requirements for explicit certificate policy indication and whether certificate policy mapping are allowed; * restrictions on the certificate path length. The signature validation policy identifies constraints on these parameters. B.6 Revocation Rules The signature policy should defines rules specifying requirements for the use of certificate revocation lists (CRLs) and/or on-line certificate status check service to check the validity of a certificate. These rules specify the mandated minimum checks that must be carried out. It is expected that in many cases either check may be selected with CRLs checks being carried out for certificate status that are unavailable from OCSP servers. The verifier may take into account information in the certificate in deciding how best to check the revocation status (e.g., a certificate extension field about authority information access or a CRL distribution point) provided that it does not conflict with the signature policy revocation rules. B.7 Rules for the Use of Roles Roles can be supported as claimed roles or as certified roles using Attribute Certificates. B.7.1 Attribute Values When signature under a role is mandated by the signature policy, then either Attribute Certificates may be used or the signer may provide a claimed role attribute. The acceptable attribute types or values may be dependent on the type of commitment. For example, a user may have several roles that allow the user to sign data that imply commitments based on one or more of his roles. Ross, et al. Experimental [Page 39]
RFC 3125 Electronic Signature Policies September 2001 B.7.2 Trust Points for Certified Attributes When a signature under a certified role is mandated by the signature policy, Attribute Authorities are used and need to be validated as part of the overall validation of the electronic signature. The trust points for Attribute Authorities do not need to be the same as the trust points to evaluate a certificate from the CA of the signer. Thus the trust point for verifying roles need not be the same as trust point used to validate the certificate path of the user's key. Naming and certification policy constraints may apply to the AA in similar circumstance to when they apply to CA. Constraints on the AA and CA need not be exactly the same. AA(s) may be used when a signer is creating a signature on behalf of an organization, they can be particularly useful when the signature represents an organizational role. AA(s) may or may not be the same authority as CA(s). Thus, the Signature Policy identifies trust points that can be used for Attribute Authorities, either by reference to the same trust points as used for Certification Authorities, or by an independent list. B.7.3 Certification Path for Certified Attributes Attribute Authorities may be organized in a tree structure in similar way to CA where the AAs are the leafs of such a tree. Naming and other constraints may be required on attribute certificate paths in a similar manner to other electronic signature certificate paths. Thus, the Signature Policy identify constraints on the following parameters used as input to the certificate path processing: * acceptable certificate policies, including requirements for explicit certificate policy indication and whether certificate policy mapping is allowed; * naming constraints in terms of constrained and excluded naming subtrees; * restrictions on the certificate path length. B.8 Rules for the Use of Time-Stamping and Timing The following rules should be used when specifying, constraints on the certificate paths for time-stamping authorities, constraints on the time-stamping authority names and general timing constraints. Ross, et al. Experimental [Page 40]
RFC 3125 Electronic Signature Policies September 2001 B.8.1 Trust Points and Certificate Paths Signature keys from time-stamping authorities will need to be supported by a certification path. The certification path used for time-stamping authorities requires a trustpoint and possibly path constraints in the same way that the certificate path for the signer's key. B.8.2 Time-Stamping Authority Names Restrictions may need to be placed by the validation policy on the named entities that may act a time-stamping authorities. B.8.3 Timing Constraints - Caution Period Before an electronic signature may really be valid, the verifier has to be sure that the holder of the private key was really the only one in possession of key at the time of signing. However, there is an inevitable delay between a compromise or loss of key being noted, and a report of revocation being distributed. To allow greater confidence in the validity of a signature, a "cautionary period" may be identified before a signature may be said to be valid with high confidence. A verifier may revalidate a signature after this cautionary signature, or wait for this period before validating a signature. The validation policy may specify such a cautionary period. B.8.4 Timing Constraints - Time-Stamp Delay There will be some delay between the time that a signature is created and the time the signer's digital signature is time-stamped. However, the longer this elapsed period the greater the risk of the signature being invalidated due to compromise or deliberate revocation of its private signing key by the signer. Thus the signature policy should specify a maximum acceptable delay between the signing time as claimed by the signer and the time included within the time-stamp. B.9 Rules for Verification Data to be followed By specifying the requirements on the signer and verifier the responsibilities of the two parties can be clearly defined to establish all the necessary information. Ross, et al. Experimental [Page 41]
RFC 3125 Electronic Signature Policies September 2001 These verification data rules should include: * requirements on the signer to provide given signed attributes; * requirements on the verifier to obtain additional certificates, CRLs, results of on line certificate status checks and to use time-stamps (if no already provided by the signer). B.10 Rules for Algorithm Constraints and Key Lengths The signature validation policy may identify a set of signing algorithms (hashing, public key, combinations) and minimum key lengths that may be used: * by the signer in creating the signature; * in end entity public key Certificates; * CA Certificates; * attribute Certificates; * by the time-stamping authority. B.11 Other Signature Policy Rules The signature policy may specify additional policy rules, for example rules that relate to the environment used by the signer. These additional rules may be defined in computer processable and/or human readable form. B.12 Signature Policy Protection When signer or verifier obtains a copy of the Signature Policy from an issuer, the source should be authenticated (for example by using electronic signatures). When the signer references a signature policy the Object Identifier (OID) of the policy, the hash value and the hash algorithm OID of that policy must be included in the Electronic Signature. It is a mandatory requirement of this present document that the signature policy value computes to one, and only one hash value using the specified hash algorithm. This means that there must be a single binary value of the encoded form of the signature policy for the unique hash value to be calculated. For example, there may exist a particular file type, length and format on which the hash value is calculated which is fixed and definitive for a particular signature policy. Ross, et al. Experimental [Page 42]
RFC 3125 Electronic Signature Policies September 2001 The hash value may be obtained by: the signer performing his own computation of the hash over the signature policy using his preferred hash algorithm permitted by the signature policy, and the definitive binary encoded form. the signer, having verified the source of the policy, may use both the hash algorithm and the hash value included in the computer processable form of the policy (see section 6.1). Ross, et al. Experimental [Page 43]
RFC 3125 Electronic Signature Policies September 2001 Full Copyright Statement Copyright (C) The Internet Society (2001). All Rights Reserved. This document and translations of it may be copied and furnished to others, and derivative works that comment on or otherwise explain it or assist in its implementation may be prepared, copied, published and distributed, in whole or in part, without restriction of any kind, provided that the above copyright notice and this paragraph are included on all such copies and derivative works. However, this document itself may not be modified in any way, such as by removing the copyright notice or references to the Internet Society or other Internet organizations, except as needed for the purpose of developing Internet standards in which case the procedures for copyrights defined in the Internet Standards process must be followed, or as required to translate it into languages other than English. The limited permissions granted above are perpetual and will not be revoked by the Internet Society or its successors or assigns. This document and the information contained herein is provided on an "AS IS" basis and THE INTERNET SOCIETY AND THE INTERNET ENGINEERING TASK FORCE DISCLAIMS ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Acknowledgement Funding for the RFC Editor function is currently provided by the Internet Society. Ross, et al. Experimental [Page 44]