- Cisco IOS PKI Overview Understanding and Planning a PKI
- Deploying RSA Keys Within a PKI
- Configuring Authorization and Revocation of Certificates in a PKI
- Configuring Certificate Enrollment for a PKI
- Configuring and Managing a Cisco IOS Certificate Server for PKI Deployment
- Storing PKI Credentials
- Source Interface Selection for Outgoing Traffic with Certificate Authority
- Finding Feature Information
- Prerequisites for PKI Certificate Enrollment
- Information About Certificate Enrollment for a PKI
- How to Configure Certificate Enrollment for a PKI
- Configuring Certificate Enrollment or Autoenrollment Example
- Configuring Autoenrollment Example
- Configuring Certificate Autoenrollment with Key Regeneration Example
- Configuring Cut-and-Paste Certificate Enrollment Example
- Configuring Manual Certificate Enrollment with Key Regeneration Example
- Creating and Verifying a Persistent Self-Signed Certificate Example
- Configuring Direct HTTP Enrollment Example
Configuring Certificate Enrollment for a PKI
This module describes the different methods available for certificate enrollment and how to set up each method for a participating PKI peer. Certificate enrollment, which is the process of obtaining a certificate from a certification authority (CA), occurs between the end host that requests the certificate and the CA. Each peer that participates in the public key infrastructure (PKI) must enroll with a CA.
Note |
Security threats, as well as the cryptographic technologies to help protect against them, are constantly changing. For more information about the latest Cisco cryptographic recommendations, see the Next Generation Encryption (NGE) white paper. |
- Finding Feature Information
- Prerequisites for PKI Certificate Enrollment
- Information About Certificate Enrollment for a PKI
- How to Configure Certificate Enrollment for a PKI
- Configuration Examples for PKI Certificate Enrollment Requests
- Additional References
- Feature Information for PKI Certificate Enrollment
Finding Feature Information
Your software release may not support all the features documented in this module. For the latest caveats and feature information, see Bug Search Tool and the release notes for your platform and software release. To find information about the features documented in this module, and to see a list of the releases in which each feature is supported, see the feature information table at the end of this module.
Use Cisco Feature Navigator to find information about platform support and Cisco software image support. To access Cisco Feature Navigator, go to www.cisco.com/go/cfn. An account on Cisco.com is not required.
Prerequisites for PKI Certificate Enrollment
Before configuring peers for certificate enrollment, you should have the following items:
- A generated Rivest, Shamir, and Adelman (RSA) key pair to enroll and a PKI in which to enroll.
- An authenticated CA.
- Familiarity with the module "Cisco IOS PKI Overview: Understanding and Planning a PKI."
Note |
As of Cisco IOS Release 12.3(7)T, all commands that begin with "crypto ca" have been changed to begin with "crypto pki." Although the router will still accept crypto ca commands, all output will be be displayed crypto pki. |
Information About Certificate Enrollment for a PKI
- What Are CAs
- Framework for Multiple CAs
- Authentication of the CA
- Supported Certificate Enrollment Methods
- Registration Authorities
- Automatic Certificate Enrollment
- Certificate Enrollment Profiles
What Are CAs
A CA is an entity that issues digital certificates that other parties can use. It is an example of a trusted third party. CAs are characteristic of many PKI schemes.
A CA manages certificate requests and issues certificates to participating network devices. These services provide centralized key management for the participating devices to validate identities and to create digital certificates. Before any PKI operations can begin, the CA generates its own public key pair and creates a self-signed CA certificate; thereafter, the CA can sign certificate requests and begin peer enrollment for the PKI.
You can use the Cisco IOS certificate server or a CA provided by a third-party CA vendor.
Framework for Multiple CAs
A PKI can be set up in a hierarchical framework to support multiple CAs. At the top of the hierarchy is a root CA, which holds a self-signed certificate. The trust within the entire hierarchy is derived from the RSA key pair of the root CA. The subordinate CAs within the hierarchy can be enrolled with either the root CA or with another subordinate CA. Multiple tiers of CAs are configured by either the root CA or with another subordinate CA. Within a hierarchical PKI, all enrolled peers can validate the certificate of one another if the peers share a trusted root CA certificate or a common subordinate CA.
When to Use Multiple CAs
Multiple CAs provide users with added flexibility and reliability. For example, subordinate CAs can be placed in branch offices while the root CA is at the office headquarters. Also, different granting policies can be implemented per CA, so you can set up one CA to automatically grant certificate requests while another CA within the hierarchy requires each certificate request to be manually granted.
Scenarios in which at least a two-tier CA is recommended are as follows:
- Large and very active networks in which a large number of certificates are revoked and reissued. A multiple tier CA helps to control the size of the certificate revocation lists (CRLs).
- When online enrollment protocols are used, the root CA can be kept offline except to issue subordinate CA certificates. This scenario provides added security for the root CA.
Authentication of the CA
The certificate of the CA must be authenticated before the device will be issued its own certificate and before certificate enrollment can occur. Authentication of the CA typically occurs only when you initially configure PKI support at your router. To authenticate the CA, issue the crypto pki authenticate command, which authenticates the CA to your router by obtaining the self-signed certificate of the CA that contains the public key of the CA.
Authentication via the fingerprint Command
Cisco IOS Release 12.3(12) and later releases allow you to issue the fingerprint command t o preenter a fingerprint that can be matched against the fingerprint of a CA certificate during authentication.
If a fingerprint is not preentered for a trustpoint, and if the authentication request is interactive, you must verify the fingerprint that is displayed during authentication of the CA certificate. If the authentication request is noninteractive, the certificate will be rejected without a preentered fingerprint.
Note |
If the authentication request is made using the command-line interface (CLI), the request is an interactive request. If the authentication request is made using HTTP or another management tool, the request is a noninteractive request. |
Supported Certificate Enrollment Methods
Cisco IOS software supports the following methods to obtain a certificate from a CA:
- Simple Certificate Enrollment Protocol (SCEP)--A Cisco-developed enrollment protocol that uses HTTP to communicate with the CA or registration authority (RA). SCEP is the most commonly used method for sending and receiving requests and certificates.
Note |
To take advantage of automated certificate and key rollover functionality, you must be running a CA that supports rollover and SCEP must be used as your client enrollment method. If you are running a Cisco IOS CA, you must be running Cisco IOS Release 12.4(2)T or a later release for rollover support. |
- PKCS12--The router imports certificates in PKCS12 format from an external server.
- IOS File System (IFS)--The router uses any file system that is supported by Cisco IOS software (such as TFTP, FTP, flash, and NVRAM) to send a certificate request and to receive the issued certificate. Users may enable IFS certificate enrollment when their CA does not support SCEP.
Note |
Prior to Cisco IOS Release 12.3(4)T, only the TFTP file system was supported within IFS. |
- Manual cut-and-paste--The router displays the certificate request on the console terminal, allowing the user to enter the issued certificate on the console terminal. A user may manually cut-and-paste certificate requests and certificates when there is no network connection between the router and CA.
- Enrollment profiles--The router sends HTTP-based enrollment requests directly to the CA server instead of to the RA-mode certificate server (CS). Enrollment profiles can be used if a CA server does not support SCEP.
- Self-signed certificate enrollment for a trustpoint--The secure HTTP (HTTPS) server generates a self-signed certificate that is to be used during the secure socket layer (SSL) handshake, establishing a secure connection between the HTTPS server and the client. The self-signed certificate is then saved in the router's startup configuration (NVRAM). The saved, self-signed certificate can then be used for future SSL handshakes, eliminating the user intervention that was necessary to accept the certificate every time the router reloaded.
Note |
To take advantage of autoenrollment and autoreenrollment, do not use either TFTP or manual cut-and-paste enrollment as your enrollment method. Both TFTP and manual cut-and-paste enrollment methods are manual enrollment processes, requiring user input. |
Cisco IOS Suite-B Support for Certificate Enrollment for a PKI
Suite-B requirements comprise of four user interface suites of cryptographic algorithms for use with IKE and IPSec that are described in RFC 4869. Each suite consists of an encryption algorithm, a digital signature algorithm, a key agreement algorithm, and a hash or message digest algorithm.
Suite-B adds the following support for the certificate enrollment for a PKI:
- Elliptic Curve Digital Signature Algorithm (ECDSA) (256-bit and 384-bit curves) is used for the signature operation within X.509 certificates.
- PKI support for validation of for X.509 certificates using ECDSA signatures.
- PKI support for generating certificate requests using ECDSA signatures and for importing the issued certificates into IOS.
See the Configuring Security for VPNs with IPsec feature module for more detailed information about Cisco IOS Suite-B support.
Registration Authorities
A Cisco IOS certificate server can be configured to run in RA mode. An RA offloads authentication and authorization responsibilities from a CA. When the RA receives a SCEP or manual enrollment request, the administrator can either reject or grant it on the basis of local policy. If the request is granted, it will be forwarded to the issuing CA, and the CA can be configured to automatically generate the certificate and return it to the RA. The client can later retrieve the granted certificate from the RA.
Automatic Certificate Enrollment
Automatic certificate enrollment allows the CA client to automatically request a certificate from its CA sever. This automatic router request eliminates the need for operator intervention when the enrollment request is sent to the CA server. Automatic enrollment is performed on startup for any trustpoint CA that is configured and that does not have a valid client certificate. When the certificate expires, a new certificate is automatically requested.
Note |
When automatic enrollment is configured, clients automatically request client certificates. The CA server performs its own authorization checks; if these checks include a policy to automatically issue certificates, all clients will automatically receive certificates, which is not very secure. Thus, automatic certificate enrollment should be combined with additional authentication and authorization mechanisms (such as Secure Device Provisioning (SDP), leveraging existing certificates, and one-time passwords). |
Automated Client Certificate and Key Rollover
By default, the automatic certificate enrollment function requests a new client certificate and keys from the CS before the client's current certificate expires. Certificate and key rollover allows the certificate renewal rollover request to be made before the certificate expires by retaining the current key and certificate until the new, or rollover, certificate is available. After a specified amount of time, the rollover certificate and keys will become the active certificate and keys. The expired certificate and keys are immediately deleted upon rollover and removed from the certificate chain and CRL.
The setup for automatic rollover is twofold: CA clients must be automatically enrolled and the client's CAs must be automatically enrolled and have the auto-rollover command enabled. For more information on configuring your CA servers for automatic certificate rollover see the section "Automatic CA Certificate and Key Rollover" in the chapter "Configuring and Managing a Cisco IOS Certificate Server for PKI Deployment " of the Public Key Infrastructure Configuration Guide.
An optional renewal percentage parameter can be used with the auto-enroll command to allow a new certificate to be requested when a specified percentage of the lifetime of the certificate has passed. For example, if the renewal percentage is configured as 90 and the certificate has a lifetime of one year, a new certificate is requested 36.5 days before the old certificate expires. In order for automatic rollover to occur, the renewal percentage must be less than 100.The specified percent value must not be less than 10. If a client certificate is issued for less than the configured validity period due to the impending expiration of the CA certificate, the rollover certificate will be issued for the balance of that period. A minimum of 10 percent of the configured validity period, with an absolute minimum of 3 minutes, is required to allow rollover enough time to function.
Tip |
If CA autoenrollment is not enabled, you may manually initiate rollover on an existing client with the crypto pki enroll command if the expiration time of the current client certificate is equal to or greater than the expiration time of the corresponding CA certificate. The client will initiate the rollover process, which occurs only if the server is configured for automated rollover and has an available rollover server certificate. |
Note |
A key pair is also sent if configured by the auto-enroll re-generate command and keyword. It is recommended that a new key pair be issued for security reasons. |
Certificate Enrollment Profiles
Certificate enrollment profiles allow users to specify certificate authentication, enrollment, and reenrollment parameters when prompted. The values for these parameters are referenced by two templates that make up the profile. One template contains parameters for the HTTP request that is sent to the CA server to obtain the certificate of the CA (also known as certificate authentication); the other template contains parameters for the HTTP request that is sent to the CA for certificate enrollment.
Configuring two templates enables users to specify different URLs or methods for certificate authentication and enrollment; for example, authentication (getting the certificate of the CA) can be performed via TFTP (using the authentication url command) and enrollment can be performed manually (using the enrollment terminal command).
Prior to Cisco IOS Release 12.3(11)T, certificate requests could be sent only in a PKCS10 format; however, an additional parameter was added to the profile, allowing users to specify the PKCS7 format for certificate renewal requests.
Note |
A single enrollment profile can have up to three separate sections for each task--certificate authentication, enrollment, and reenrollment. |
How to Configure Certificate Enrollment for a PKI
This section contains the following enrollment option procedures. If you configure enrollment or autoenrollment (the first task), you cannot configure manual certificate enrollment. Also, if you configure TFTP or manual cut-and-paste certificate enrollment, you cannot configure autoenrollment, autoreenrollment, an enrollment profile, nor can you utilize the automated CA certificate rollover capability.
- Configuring Certificate Enrollment or Autoenrollment
- Configuring Manual Certificate Enrollment
- Configuring a Persistent Self-Signed Certificate for Enrollment via SSL
- Configuring a Certificate Enrollment Profile for Enrollment or Reenrollment
Configuring Certificate Enrollment or Autoenrollment
Perform this task to configure certificate enrollment or autoenrollment for clients participating in your PKI.
Before configuring automatic certificate enrollment requests, you should ensure that all necessary enrollment information is configured.
Prerequisites for Enabling Automated Client Certificate and Key Rollover
CA client support for certificate rollover is automatically enabled when using autoenrollment. For automatic CA certificate rollover to run successfully, the following prerequisites are applicable:
- Your network devices must support shadow PKI.
- Your clients must be running Cisco IOS Release 12.4(2)T or a later release.
- The client's CS must support automatic rollover. See the section "Automatic CA Certificate and Key Rollover" in the chapter "Configuring and Managing a Cisco IOS Certificate Server for PKI Deployment " of the Public Key Infrastructure Configuration Guide for more information on CA server automatic rollover configuration.
Prerequisites for Specifying Autoenrollment Initial Key Generation Location
To specify the location of the autoenrollment initial key generation, you must be running Cisco IOS Release 12.4(11)T or a later release.
DETAILED STEPS
Configuring Manual Certificate Enrollment
Manual certificate enrollment can be set up via TFTP or the manual cut-and-paste method. Both options can be used if your CA does not support SCEP or if a network connection between the router and CA is not possible. Perform one of the following tasks to set up manual certificate enrollment:
- PEM-Formatted Files for Certificate Enrollment Request
- Restrictions for Manual Certificate Enrollment
- Configuring Cut-and-Paste Certificate Enrollment
- Configuring TFTP Certificate Enrollment
- Certifying a URL Link for Secure Communication with a Trend Micro Server
PEM-Formatted Files for Certificate Enrollment Request
Using PEM-formatted files for certificate requests can be helpful for customers who are using terminal or profile-based enrollment to request certificates from their CA server. Customers using PEM-formatted files can directly use existing certificates on their routers.
Restrictions for Manual Certificate Enrollment
SCEP Restriction
We do not recommend switching URLs if SCEP is used; that is, if the enrollment URL is "http://myca," do not change the enrollment URL after getting the CA certificate and before enrolling the certificate. A user can switch between TFTP and manual cut-and-paste.
Key Regeneration Restriction
Do not regenerate the keys manually using the crypto key generate command; key regeneration will occur when the crypto pki enrollcommand is issued if the regenerate keyword is specified.
Configuring Cut-and-Paste Certificate Enrollment
Perform this task to configure cut-and-paste certificate enrollment. This task helps you to configure manual certificate enrollment via the cut-and-paste method for peers participating in your PKI.
DETAILED STEPS
Command or Action | Purpose | |||||
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Example: Router> enable |
Enables privileged EXEC mode.
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Example: Router# configure terminal |
Enters global configuration mode. |
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Example: Router(config)# crypto pki trustpoint mytp |
Declares the trustpoint and a given name and enters ca-trustpoint configuration mode. |
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Example: Router(ca-trustpoint)# enrollment terminal |
Specifies the manual cut-and-paste certificate enrollment method.
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Example: Router(ca-trustpoint)# fingerprint 12EF53FA 355CD23E 12EF53FA 355CD23E |
(Optional) Specifies a fingerprint that can be matched against the fingerprint of a CA certificate during authentication.
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Example: Router(ca-trustpoint)# exit |
Exits ca-trustpoint configuration mode and returns to global configuration mode. |
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Example: Router(config)# crypto pki authenticate mytp |
Retrieves the CA certificate and authenticates it. |
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Example: Router(config)# crypto pki enroll mytp |
Generates certificate request and displays the request for copying and pasting into the certificate server.
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Example: Router(config)# crypto pki import mytp certificate |
Imports a certificate manually at the console terminal (pasting).
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Example: Router(config)# exit |
Exits global configuration mode. |
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Example: Router# show crypto pki certificates |
(Optional) Displays information about your certificates, the certificates of the CA, and RA certificates. |
Configuring TFTP Certificate Enrollment
Perform this task to configure TFTP certificate enrollment. This task helps you to configure manual certificate enrollment using a TFTP server.
- You must know the correct URL to use if you are configuring certificate enrollment via TFTP.
- The router must be able to write a file to the TFTP server for the crypto pki enroll command.
- If you are using a file specification with the enrollment command, the file must contain the CA certificate either in binary format or be base-64 encoded.
- You must know if your CA ignores key usage information in a certificate request and issues only a general purpose usage certificate.
Caution |
Some TFTP servers require that the file must exist on the server before it can be written. Most TFTP servers require files that can be written over. This requirement may pose a risk because any router or other device may write or overwrite the certificate request; thus, the replacement certificate request will not be used by the CA administrator, who must first check the enrollment request fingerprint before granting the certificate request. |
DETAILED STEPS
Command or Action | Purpose | |||
---|---|---|---|---|
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Example: Router> enable |
Enables privileged EXEC mode.
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Example: Router# configure terminal |
Enters global configuration mode. |
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Example: Router(config)# crypto pki trustpoint mytp |
Declares the trustpoint and a given name and enters ca-trustpoint configuration mode. |
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Example: Router(ca-trustpoint)# enrollment url tftp://certserver/file_specification |
Specifies TFTP as the enrollment method to send the enrollment request and to retrieve the CA certificate and router certificate and any optional parameters.
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Example: Router(ca-trustpoint)# fingerprint 12EF53FA 355CD23E 12EF53FA 355CD23E |
(Optional) Specifies the fingerprint of the CA certificate received via an out-of-band method from the CA administrator.
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Example: Router(ca-trustpoint)# exit |
Exits ca-trustpoint configuration mode and returns to global configuration mode. |
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Example: Router(config)# crypto pki authenticate mytp |
Retrieves the CA certificate and authenticates it from the specified TFTP server. |
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Example: Router(config)# crypto pki enroll mytp |
Generates certificate request and writes the request out to the TFTP server.
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Example: Router(config)# crypto pki import mytp certificate |
Imports a certificate via TFTP at the console terminal, which retrieves the granted certificate.
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Example: Router(config)# exit |
Exits global configuration mode. |
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Example: Router# show crypto pki certificates |
(Optional) Displays information about your certificates, the certificates of the CA, and RA certificates. |
Certifying a URL Link for Secure Communication with a Trend Micro Server
Perform this task to certify a link used in URL filtering that allows secure communication with a Trend Micro Server.
Note |
Security threats, as well as the cryptographic technologies to help protect against them, are constantly changing. For more information about the latest Cisco cryptographic recommendations, see the Next Generation Encryption (NGE) white paper. |
DETAILED STEPS
Command or Action | Purpose | |||
---|---|---|---|---|
|
Example: Router> enable |
Enables privileged EXEC mode. |
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Example: Router# clock set 23:22:00 22 Dec 2009 |
Sets the clock on the router. |
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Example: Router# configure terminal |
Enters global configuration mode. |
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Example: Router(config)# clock timezone PST -08 |
Sets the time zone.
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Example: Router(config)# ip http server |
Enables the HTTP server. |
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Example: Router(config)# hostname hostname1 |
Configures the hostname of the router. |
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Example: Router(config)# ip domain-name example.com |
Defines the domain name for the router. |
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Example: Router(config)# crypto key generate rsa general-keys modulus general |
Generates the crypto keys.
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Example: Router(config)# crypto pki trustpoint mytp |
Declares the CA that your router should use and enters ca-trustpoint configuration mode.
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Example: Router(ca-trustpoint)# enrollment terminal |
Specifies the manual cut-and-paste certificate enrollment method. |
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Example: Router(ca-trustpoint)# crypto ca authenticate mytp |
Takes the name of the CA as the argument and authenticates it. Enter the base 64 encoded CA certificate. End with a blank line or the word "quit" on a line by itself. |
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MIIDIDCCAomgAwIBAgIENd70zzANBgkqhkiG9w0BAQUFADBOMQswCQYDVQQGEwJV UzEQMA4GA1UEChMHRXF1aWZheDEtMCsGA1UECxMkRXF1aWZheCBTZWN1cmUgQ2Vy dGlmaWNhdGUgQXV0aG9yaXR5MB4XDTk4MDgyMjE2NDE1MVoXDTE4MDgyMjE2NDE1 MVowTjELMAkGA1UEBhMCVVMxEDAOBgNVBAoTB0VxdWlmYXgxLTArBgNVBAsTJEVx dWlmYXggU2VjdXJlIENlcnRpZmljYXRlIEF1dGhvcml0eTCBnzANBgkqhkiG9w0B AQEFAAOBjQAwgYkCgYEAwV2xWGcIYu6gmi0fCG2RFGiYCh7+2gRvE4RiIcPRfM6f BeC4AfBONOziipUEZKzxa1NfBbPLZ4C/QgKO/t0BCezhABRP/PvwDN1Dulsr4R+A cJkVV5MW8Q+XarfCaCMczE1ZMKxRHjuvK9buY0V7xdlfUNLjUA86iOe/FP3gx7kC AwEAAaOCAQkwggEFMHAGA1UdHwRpMGcwZaBjoGGkXzBdMQswCQYDVQQGEwJVUzEQ MA4GA1UEChMHRXF1aWZheDEtMCsGA1UECxMkRXF1aWZheCBTZWN1cmUgQ2VydGlm aWNhdGUgQXV0aG9yaXR5MQ0wCwYDVQQDEwRDUkwxMBoGA1UdEAQTMBGBDzIwMTgw ODIyMTY0MTUxWjALBgNVHQ8EBAMCAQYwHwYDVR0jBBgwFoAUSOZo+SvSspXXR9gj IBBPM5iQn9QwHQYDVR0OBBYEFEjmaPkr0rKV10fYIyAQTzOYkJ/UMAwGA1UdEwQF MAMBAf8wGgYJKoZIhvZ9B0EABA0wCxsFVjMuMGMDAgbAMA0GCSqGSIb3DQEBBQUA A4GBAFjOKer89961zgK5F7WF0bnj4JXMJTENAKaSbn+2kmOeUJXRmm/kEd5jhW6Y 7qj/WsjTVbJmcVfewCHrPSqnI0kBBIZCe/zuf6IWUrVnZ9NA2zsmWLIodz2uFHdh 1voqZiegDfqnc1zqcPGUIWVEX/r87yloqaKHee9570+sB3c4 The following command output displays: Certificate has the following attributes: Fingerprint MD5: 67CB9DC0 13248A82 9BB2171E D11BECD4 Fingerprint SHA1: D23209AD 23D31423 2174E40D 7F9D6213 9786633A |
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% Do you accept this certificate? [yes/no]: yes The following command output displays: Trustpoint CA certificate accepted. % Certificate successfully imported |
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Example: hostname1(ca-trustpoint)# serial-number |
Specifies the router serial number in the certificate request. |
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Example: hostname1(ca-trustpoint)# revocation-check none Example:
|
Specifies that certificate checking is ignored. |
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Example: hostname1(ca-trustpoint)# end |
Exits ca-trustpoint configuration mode and returns to privileged EXEC mode. |
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Example: hostname1# trm register |
Manually starts the Trend Micro Server registration process. |
Configuring a Persistent Self-Signed Certificate for Enrollment via SSL
This section contains the following tasks:
Note |
These tasks are optional because if you enable the HTTPS server, it generates a self-signed certificate automatically using default values. |
- Persistent Self-Signed Certificates Overview
- Restrictions
- Configuring a Trustpoint and Specifying Self-Signed Certificate Parameters
- Enabling the HTTPS Server
Persistent Self-Signed Certificates Overview
The SSL protocol can be used to establish a secure connection between an HTTPS server and a client (web browser). During the SSL handshake, the client expects the SSL server's certificate to be verifiable using a certificate the client already possesses.
If Cisco IOS software does not have a certificate that the HTTPS server can use, the server generates a self-signed certificate by calling a PKI application programming interface (API). When the client receives this self-signed certificate and is unable to verify it, intervention is needed. The client asks you if the certificate should be accepted and saved for future use. If you accept the certificate, the SSL handshake continues.
Future SSL handshakes between the same client and the server use the same certificate. However, if the router is reloaded, the self-signed certificate is lost. The HTTPS server must then create a new self-signed certificate. This new self-signed certificate does not match the previous certificate, so you are once again asked to accept it.
Requesting acceptance of the router's certificate each time that the router reloads may present an opportunity for an attacker to substitute an unauthorized certificate when you are being asked to accept the certificate. Persistent self-signed certificates overcome all these limitations by saving a certificate in the router's startup configuration.
Restrictions
You can configure only one trustpoint for a persistent self-signed certificate.
Note |
Do not change the IP domain name or the hostname of the router after creating the self-signed certificate. Changing either name triggers the regeneration of the self-signed certificate and overrides the configured trustpoint. WebVPN ties the SSL trustpoint name to the WebVPN gateway configuration. If a new self-signed certificate is triggered, then the new trustpoint name does not match the WebVPN configuration, causing the WebVPN connections to fail. |
Configuring a Trustpoint and Specifying Self-Signed Certificate Parameters
Perform the following task to configure a trustpoint and specify self-signed certificate parameters.
DETAILED STEPS
Command or Action | Purpose | |||
---|---|---|---|---|
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Example: Router> enable |
Enables privileged EXEC mode.
|
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Example: Router# configure terminal |
Enters global configuration mode. |
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Example: Router(config)# crypto pki trustpoint local |
Declares the CA that your router should use and enters ca-trustpoint configuration mode.
|
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Example: Router(ca-trustpoint)# enrollment selfsigned |
Specifies self-signed enrollment. |
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Example: Router(ca-trustpoint)# subject-name |
(Optional) Specifies the requested subject name to be used in the certificate request.
|
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Example: Router(ca-trustpoint)# rsakeypair examplekeys 1024 1024 |
(Optional) Specifies which key pair to associate with the certificate.
|
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Example: Router(ca-trustpoint)# crypto pki enroll local |
Tells the router to generate the persistent self-signed certificate. |
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Example: Router(ca-trustpoint)# end |
(Optional) Exits ca-trustpoint configuration mode.
|
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Example: Router# show crypto pki certificates local verbose |
Displays information about your certificate, the certification authority certificate, and any registration authority certificates. |
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|
Example: Router# show crypto pki trustpoints status |
Displays the trustpoints that are configured in the router. |
Enabling the HTTPS Server
Perform the following task to enable the HTTPS server.
To specify parameters, you must create a trustpoint and configure it. To use default values, delete any existing self-signed trustpoints. Deleting all self-signed trustpoints causes the HTTPS server to generate a persistent self-signed certificate using default values as soon as the server is enabled.
DETAILED STEPS
Command or Action | Purpose | |||
---|---|---|---|---|
|
Example: Router> enable |
Enables privileged EXEC mode.
|
||
|
Example: Router# configure terminal |
Enters global configuration mode. |
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Example: Router(config)# ip http secure-server |
Enables the HTTPS web server.
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Example: Router(config)# end |
Exits global configuration mode. |
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Example: Router# copy system:running-config nvram: startup-config |
Saves the self-signed certificate and the HTTPS server in enabled mode. |
Configuring a Certificate Enrollment Profile for Enrollment or Reenrollment
Perform this task to configure a certificate enrollment profile for enrollment or reenrollment. This task helps you to configure an enrollment profile for certificate enrollment or reenrollment of a router with a Cisco IOS CA that is already enrolled with a third-party vendor CA.
Enable a router that is enrolled with a third-party vendor CA to use its existing certificate to enroll with the Cisco IOS certificate server so the enrollment request is automatically granted. To enable this functionality, you must issue the enrollment credential command. Also, you cannot configure manual certificate enrollment.
Perform the following tasks at the client router before configuring a certificate enrollment profile for the client router that is already enrolled with a third-party vendor CA so that the router can reenroll with a Cisco IOS certificate server:
- Defined a trustpoint that points to the third-party vendor CA.
- Authenticated and enrolled the client router with the third-party vendor CA.
Note |
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DETAILED STEPS
Command or Action | Purpose | |||
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Example: Router> enable |
Enables privileged EXEC mode. |
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Example: Router# configure terminal |
Enters global configuration mode. |
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Example: Router(config)# crypto pki trustpoint Entrust |
Declares the trustpoint and a given name and enters ca-trustpoint configuration mode. |
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Example: Router(ca-trustpoint)# enrollment profile E |
Specifies that an enrollment profile is to be used for certificate authentication and enrollment. |
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Example: Router(ca-trustpoint)# exit |
Exits ca-trustpoint configuration mode. |
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Example: Router(config)# crypto pki profile enrollment E |
Defines an enrollment profile and enters ca-profile-enroll configuration mode. |
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Example: Router(ca-profile-enroll)# authentication url http://entrust:81 Example: Router(ca-profile-enroll)# authentication terminal |
Specifies the URL of the CA server to which to send certificate authentication requests.
Specifies manual cut-and-paste certificate authentication. |
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Example: Router(ca-profile-enroll)# authentication command |
(Optional) Specifies the HTTP command that is sent to the CA for authentication. | ||
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Example: Router(ca-profile-enroll)# enrollment url http://entrust:81/cda-cgi/clientcgi.exe Example:
Example: Router(ca-profile-enroll)# enrollment terminal |
Specifies the URL of the CA server to which to send certificate enrollment requests via HTTP or TFTP. Specifies manual cut-and-paste certificate enrollment. |
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Example: Router(ca-profile-enroll)# enrollment credential Entrust |
(Optional) Specifies the third-party vendor CA trustpoint that is to be enrolled with the Cisco IOS CA.
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Example: Router(ca-profile-enroll)# enrollment command |
(Optional) Specifies the HTTP command that is sent to the CA for enrollment. |
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Example: Router(ca-profile-enroll)# parameter 1 value aaaa-bbbb-cccc |
(Optional) Specifies parameters for an enrollment profile. |
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Example: Router(ca-profile-enroll)# exit |
(Optional) Exits ca-profile-enroll configuration mode. |
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Example: Router# show crypto pki certificates |
(Optional) Displays information about your certificates, the certificates of the CA, and RA certificates. |
What to Do Next
If you configured the router to reenroll with a Cisco IOS CA, you should configure the Cisco IOS certificate server to accept enrollment requests only from clients already enrolled with the specified third-party vendor CA trustpoint to take advantage of this functionality. For more information, see the module " Configuring and Managing a Cisco IOS Certificate Server for PKI Deployment."
Configuration Examples for PKI Certificate Enrollment Requests
- Configuring Certificate Enrollment or Autoenrollment Example
- Configuring Autoenrollment Example
- Configuring Certificate Autoenrollment with Key Regeneration Example
- Configuring Cut-and-Paste Certificate Enrollment Example
- Configuring Manual Certificate Enrollment with Key Regeneration Example
- Creating and Verifying a Persistent Self-Signed Certificate Example
- Configuring Direct HTTP Enrollment Example
Configuring Certificate Enrollment or Autoenrollment Example
The following example shows the configuration for the "mytp-A" certificate server and its associated trustpoint, where RSA keys generated by the initial autoenrollment for the trustpoint will be stored on a USB token, "usbtoken0":
crypto pki server mytp-A database level complete issuer-name CN=company, L=city, C=country grant auto ! Specifies that certificate requests will be granted automatically. ! crypto pki trustpoint mytp-A revocation-check none rsakeypair myTP-A storage usbtoken0: ! Specifies that keys will be stored on usbtoken0:. on usbtoken0:
! Specifies that keys generated on initial auto enroll will be generated on and stored on ! usbtoken0:
Configuring Autoenrollment Example
The following example shows how to configure the router to automatically enroll with a CA on startup, enabling automatic rollover, and how to specify all necessary enrollment information in the configuration:
crypto pki trustpoint trustpt1 enrollment url http://trustpt1.example.com// subject-name OU=Spiral Dept., O=example.com ip-address ethernet-0 serial-number none usage ike auto-enroll regenerate password password1 rsa-key trustpt1 2048 ! crypto pki certificate chain trustpt1 certificate pki 0B 30820293 3082023D A0030201 0202010B 300D0609 2A864886 F70D0101 04050030 79310B30 09060355 04061302 5553310B 30090603 55040813 02434131 15301306 0355040A 130C4369 73636F20 53797374 656D3120 301E0603 55040B13 17737562 6F726420 746F206B 6168756C 75692049 50495355 31243022 06035504 03131B79 6E692D75 31302043 65727469 66696361 7465204D 616E6167 6572301E 170D3030 30373134 32303536 32355A17 0D303130 37313430 31323834 335A3032 310E300C 06035504 0A130543 6973636F 3120301E 06092A86 4886F70D 01090216 11706B69 2D343562 2E636973 636F2E63 6F6D305C 300D0609 2A864886 F70D0101 01050003 4B003048 024100B3 0512A201 3B4243E1 378A9703 8AC5E3CE F77AF987 B5A422C4 15E947F6 70997393 70CF34D6 63A86B9C 4347A81A 0551FC02 ABA62360 01EF7DD2 6C136AEB 3C6C3902 03010001 A381F630 81F3300B 0603551D 0F040403 02052030 1C060355 1D110415 30138211 706B692D 3435622E 63697363 6F2E636F 6D301D06 03551D0E 04160414 247D9558 169B9A21 23D289CC 2DDA2A9A 4F77C616 301F0603 551D2304 18301680 14BD742C E892E819 1D551D91 683F6DB2 D8847A6C 73308185 0603551D 1F047E30 7C307AA0 3CA03AA4 38303631 0E300C06 0355040A 13054369 73636F31 24302206 03550403 131B796E 692D7531 30204365 72746966 69636174 65204D61 6E616765 72A23AA4 38303631 0E300C06 0355040A 13054369 73636F31 24302206 03550403 131B796E 692D7531 30204365 72746966 69636174 65204D61 6E616765 72300D06 092A8648 86F70D01 01040500 03410015 BC7CECF9 696697DF E887007F 7A8DA24F 1ED5A785 C5C60452 47860061 0C18093D 08958A77 5737246B 0A25550A 25910E27 8B8B428E 32F8D948 3DD1784F 954C70 quit
Note |
In this example, keys are neither regenerated nor rolled over. |
Configuring Certificate Autoenrollment with Key Regeneration Example
The following example shows how to configure the router to automatically enroll with the CA named "trustme1" on startup and enable automatic rollover. The regenerate keyword is issued, so a new key will be generated for the certificate and reissued when the automatic rollover process is initiated. The renewal percentage is configured as 90 so if the certificate has a lifetime of one year, a new certificate is requested 36.5 days before the old certificate expires. The changes made to the running configuration are saved to the NVRAM startup configuration because autoenrollment will not update NVRAM if the running configuration has been modified but not written to NVRAM.
crypto pki trustpoint trustme1 enrollment url http://trustme1.example.com/ subject-name OU=Spiral Dept., O=example.com ip-address ethernet0 serial-number none auto-enroll 90 regenerate password password1 rsakeypair trustme1 2048 exit crypto pki authenticate trustme1 copy system:running-config nvram:startup-config
Configuring Cut-and-Paste Certificate Enrollment Example
The following example shows how to configure certificate enrollment using the manual cut-and-paste enrollment method:
Router(config)# crypto pki trustpoint TP Router(ca-trustpoint)# enrollment terminal Router(ca-trustpoint)# crypto pki authenticate TP Enter the base 64 encoded CA certificate. End with a blank line or the word "quit" on a line by itself -----BEGIN CERTIFICATE----- MIICNDCCAd6gAwIBAgIQOsCmXpVHwodKryRoqULV7jANBgkqhkiG9w0BAQUFADA5 MQswCQYDVQQGEwJVUzEWMBQGA1UEChMNQ2lzY28gU3lzdGVtczESMBAGA1UEAxMJ bXNjYS1yb290MB4XDTAyMDIxNDAwNDYwMVoXDTA3MDIxNDAwNTQ0OFowOTELMAkG A1UEBhMCVVMxFjAUBgNVBAoTDUNpc2NvIFN5c3RlbXMxEjAQBgNVBAMTCW1zY2Et cm9vdDBcMA0GCSqGSIb3DQEBAQUAA0sAMEgCQQCix8nIGFg+wvy3BjFbVi25wYoG K2N0HWWHpqxFuFhqyBnIC0OshIn9CtrdN3JvUNHr0NIKocEwNKUGYmPwWGTfAgMB AAGjgcEwgb4wCwYDVR0PBAQDAgHGMA8GA1UdEwEB/wQFMAMBAf8wHQYDVR0OBBYE FKIacsl6dKAfuNDVQymlSp7esf8jMG0GA1UdHwRmMGQwL6AtoCuGKWh0dHA6Ly9t c2NhLXJvb3QvQ2VydEVucm9sbC9tc2NhLXJvb3QuY3JsMDGgL6AthitmaWxlOi8v XFxtc2NhLXJvb3RcQ2VydEVucm9sbFxtc2NhLXJvb3QuY3JsMBAGCSsGAQQBgjcV AQQDAgEAMA0GCSqGSIb3DQEBBQUAA0EAeuZkZMX9qkoLHfETYTpVWjZPQbBmwNRA oJDSdYdtL3BcI/uLL5q7EmODyGfLyMGxuhQYx5r/40aSQgLCqBq+yg== -----END CERTIFICATE----- Certificate has the following attributes: Fingerprint: D6C12961 CD78808A 4E02193C 0790082A % Do you accept this certificate? [yes/no]: y Trustpoint CA certificate accepted. % Certificate successfully imported Router(config)# crypto pki enroll TP % Start certificate enrollment.. % The subject name in the certificate will be: Router.example.com % Include the router serial number in the subject name? [yes/no]: n % Include an IP address in the subject name? [no]: n Display Certificate Request to terminal? [yes/no]: y Signature key certificate request - Certificate Request follows: MIIBhTCB7wIBADAlMSMwIQYJKoZIhvcNAQkCFhRTYW5kQmFnZ2VyLmNpc2NvLmNv bTCBnzANBgkqhkiG9w0BAQEFAAOBjQAwgYkCgYEAxdhXFDiWAn/hIZs9zfOtssKA daoWYu0ms9Fe/Pew01dh14vXdxgacstOs2Pr5wk6jLOPxpvxOJPWyQM6ipLmyVxv ojhyLTrVohrh6Dnqcvk+G/5ohss9o9RxvONwx042pQchFnx9EkMuZC7evwRxJEqR mBHXBZ8GmP3jYQsjS8MCAwEAAaAhMB8GCSqGSIb3DQEJDjESMBAwDgYDVR0PAQH/ BAQDAgeAMA0GCSqGSIb3DQEBBAUAA4GBAMT6WtyFw95POY7UtF+YIYHiVRUf4SCq hRIAGrljUePLo9iTqyPU1Pnt8JnIZ5P5BHU3MfgP8sqodaWub6mubkzaohJ1qD06 O87fnLCNid5Tov5jKogFHIki2EGGZxBosUw9lJlenQdNdDPbJc5LIWdfDvciA6jO Nl8rOtKnt8Q+ ! ! ! Redisplay enrollment request? [yes/no]: Encryption key certificate request - Certificate Request follows: MIIBhTCB7wIBADAlMSMwIQYJKoZIhvcNAQkCFhRTYW5kQmFnZ2VyLmNpc2NvLmNv bTCBnzANBgkqhkiG9w0BAQEFAAOBjQAwgYkCgYEAwG60QojpDbzbKnyj8FyTiOcv THkDP7XD4vLT1XaJ409z0gSIoGnIcdFtXhVlBWtpq3/O9zYFXr1tH+BMCRQi3Lts 0IpxYa3D9iFPqev7SPXpsAIsY8a6FMq7TiwLObqiQjLKL4cbuV0Frjl0Yuv5A/Z+ kqMOm7c+pWNWFdLe9lsCAwEAAaAhMB8GCSqGSIb3DQEJDjESMBAwDgYDVR0PAQH/ BAQDAgUgMA0GCSqGSIb3DQEBBAUAA4GBACF7feURj/fJMojPBlR6fa9BrlMJx+2F H91YM/CIiz2n4mHTeWTWKhLoT8wUfa9NGOk7yi+nF/F7035twLfq6n2bSCTW4aem 8jLMMaeFxwkrV/ceQKrucmNC1uVx+fBy9rhnKx8j60XE25tnp1U08r6om/pBQABU eNPFhozcaQ/2 ! ! ! Redisplay enrollment request? [yes/no]: n Router(config)# crypto pki import TP certificate Enter the base 64 encoded certificate. End with a blank line or the word "quit" on a line by itself MIIDajCCAxSgAwIBAgIKFN7C6QAAAAAMRzANBgkqhkiG9w0BAQUFADA5MQswCQYD VQQGEwJVUzEWMBQGA1UEChMNQ2lzY28gU3lzdGVtczESMBAGA1UEAxMJbXNjYS1y b290MB4XDTAyMDYwODAxMTY0MloXDTAzMDYwODAxMjY0MlowJTEjMCEGCSqGSIb3 DQEJAhMUU2FuZEJhZ2dlci5jaXNjby5jb20wgZ8wDQYJKoZIhvcNAQEBBQADgY0A MIGJAoGBAMXYVxQ4lgJ/4SGbPc3zrbLCgHWqFmLtJrPRXvz3sNNXYdeL13cYGnLL TrNj6+cJOoyzj8ab8TiT1skDOoqS5slcb6I4ci061aIa4eg56nL5Phv+aIbLPaPU cbzjcMdONqUHIRZ8fRJDLmQu3r8EcSRKkZgR1wWfBpj942ELI0vDAgMBAAGjggHM MIIByDALBgNVHQ8EBAMCB4AwHQYDVR0OBBYEFL8Quz8dyz4EGIeKx9A8UMNHLE4s MHAGA1UdIwRpMGeAFKIacsl6dKAfuNDVQymlSp7esf8joT2kOzA5MQswCQYDVQQG EwJVUzEWMBQGA1UEChMNQ2lzY28gU3lzdGVtczESMBAGA1UEAxMJbXNjYS1yb290 ghA6wKZelUfCh0qvJGipQtXuMCIGA1UdEQEB/wQYMBaCFFNhbmRCYWdnZXIuY2lz Y28uY29tMG0GA1UdHwRmMGQwL6AtoCuGKWh0dHA6Ly9tc2NhLXJvb3QvQ2VydEVu cm9sbC9tc2NhLXJvb3QuY3JsMDGgL6AthitmaWxlOi8vXFxtc2NhLXJvb3RcQ2Vy dEVucm9sbFxtc2NhLXJvb3QuY3JsMIGUBggrBgEFBQcBAQSBhzCBhDA/BggrBgEF BQcwAoYzaHR0cDovL21zY2Etcm9vdC9DZXJ0RW5yb2xsL21zY2Etcm9vdF9tc2Nh LXJvb3QuY3J0MEEGCCsGAQUFBzAChjVmaWxlOi8vXFxtc2NhLXJvb3RcQ2VydEVu cm9sbFxtc2NhLXJvb3RfbXNjYS1yb290LmNydDANBgkqhkiG9w0BAQUFAANBAJo2 r6sHPGBdTQX2EDoJpR/A2UHXxRYqVSHkFKZw0z31r5JzUM0oPNUETV7mnZlYNVRZ CSEX/G8boi3WOjz9wZo= % Router Certificate successfully imported Router(config)# crypto pki import TP cert Enter the base 64 encoded certificate. End with a blank line or the word "quit" on a line by itself MIIDajCCAxSgAwIBAgIKFN7OBQAAAAAMSDANBgkqhkiG9w0BAQUFADA5MQswCQYD VQQGEwJVUzEWMBQGA1UEChMNQ2lzY28gU3lzdGVtczESMBAGA1UEAxMJbXNjYS1y b290MB4XDTAyMDYwODAxMTY0NVoXDTAzMDYwODAxMjY0NVowJTEjMCEGCSqGSIb3 DQEJAhMUU2FuZEJhZ2dlci5jaXNjby5jb20wgZ8wDQYJKoZIhvcNAQEBBQADgY0A MIGJAoGBAMButEKI6Q282yp8o/Bck4jnL0x5Az+1w+Ly09V2ieNPc9IEiKBpyHHR bV4VZQVraat/zvc2BV69bR/gTAkUIty7bNCKcWGtw/YhT6nr+0j16bACLGPGuhTK u04sCzm6okIyyi+HG7ldBa45dGLr+QP2fpKjDpu3PqVjVhXS3vZbAgMBAAGjggHM MIIByDALBgNVHQ8EBAMCBSAwHQYDVR0OBBYEFPDO29oRdlEUSgBMg6jZR+YFRWlj MHAGA1UdIwRpMGeAFKIacsl6dKAfuNDVQymlSp7esf8joT2kOzA5MQswCQYDVQQG EwJVUzEWMBQGA1UEChMNQ2lzY28gU3lzdGVtczESMBAGA1UEAxMJbXNjYS1yb290 ghA6wKZelUfCh0qvJGipQtXuMCIGA1UdEQEB/wQYMBaCFFNhbmRCYWdnZXIuY2lz Y28uY29tMG0GA1UdHwRmMGQwL6AtoCuGKWh0dHA6Ly9tc2NhLXJvb3QvQ2VydEVu cm9sbC9tc2NhLXJvb3QuY3JsMDGgL6AthitmaWxlOi8vXFxtc2NhLXJvb3RcQ2Vy dEVucm9sbFxtc2NhLXJvb3QuY3JsMIGUBggrBgEFBQcBAQSBhzCBhDA/BggrBgEF BQcwAoYzaHR0cDovL21zY2Etcm9vdC9DZXJ0RW5yb2xsL21zY2Etcm9vdF9tc2Nh LXJvb3QuY3J0MEEGCCsGAQUFBzAChjVmaWxlOi8vXFxtc2NhLXJvb3RcQ2VydEVu cm9sbFxtc2NhLXJvb3RfbXNjYS1yb290LmNydDANBgkqhkiG9w0BAQUFAANBAHaU hyCwLirUghNxCmLzXRG7C3W1j0kSX7a4fX9OxKR/Z2SoMjdMNPPyApuh8SoT2zBP ZKjZU2WjcZG/nZF4W5k= % Router Certificate successfully imported
You can verify that the certificate was successfully imported by issuing the show crypto pki certificates command:
Router# show crypto pki certificates
Certificate
Status: Available
Certificate Serial Number: 14DECE05000000000C48
Certificate Usage: Encryption
Issuer:
CN = TPCA-root
O = Company
C = US
Subject:
Name: Router.example.com
OID.1.2.840.113549.1.9.2 = Router.example.com
CRL Distribution Point:
http://tpca-root/CertEnroll/tpca-root.crl
Validity Date:
start date: 18:16:45 PDT Jun 7 2002
end date: 18:26:45 PDT Jun 7 2003
renew date: 16:00:00 PST Dec 31 1969
Associated Trustpoints: TP
Certificate
Status: Available
Certificate Serial Number: 14DEC2E9000000000C47
Certificate Usage: Signature
Issuer:
CN = tpca-root
O = company
C = US
Subject:
Name: Router.example.com
OID.1.2.840.113549.1.9.2 = Router.example.com
CRL Distribution Point:
http://tpca-root/CertEnroll/tpca-root.crl
Validity Date:
start date: 18:16:42 PDT Jun 7 2002
end date: 18:26:42 PDT Jun 7 2003
renew date: 16:00:00 PST Dec 31 1969
Associated Trustpoints: TP
CA Certificate
Status: Available
Certificate Serial Number: 3AC0A65E9547C2874AAF2468A942D5EE
Certificate Usage: Signature
Issuer:
CN = tpca-root
O = Company
C = US
Subject:
CN = tpca-root
O = company
C = US
CRL Distribution Point:
http://tpca-root/CertEnroll/tpca-root.crl
Validity Date:
start date: 16:46:01 PST Feb 13 2002
end date: 16:54:48 PST Feb 13 2007
Associated Trustpoints: TP
Configuring Manual Certificate Enrollment with Key Regeneration Example
The following example shows how to regenerate new keys with a manual certificate enrollment from the CA named "trustme2":
crypto pki trustpoint trustme2 enrollment url http://trustme2.example.com/ subject-name OU=Spiral Dept., O=example.com ip-address ethernet0 serial-number none regenerate password password1 rsakeypair trustme2 2048s exit crypto pki authenticate trustme2 crypto pki enroll trustme2
Creating and Verifying a Persistent Self-Signed Certificate Example
The following example shows how to declare and enroll a trustpoint named "local" and generate a self-signed certificate with an IP address:
crypto pki trustpoint local enrollment selfsigned end configure terminal Enter configuration commands, one per line. End with CNTL/Z. crypto pki enroll local Nov 29 20:51:13.067: %SSH-5-ENABLED: SSH 1.99 has been enabled Nov 29 20:51:13.267: %CRYPTO-6-AUTOGEN: Generated new 512 bit key pair % Include the router serial number in the subject name? [yes/no]: yes % Include an IP address in the subject name? [no]: yes Enter Interface name or IP Address[]: ethernet 0 Generate Self Signed Router Certificate? [yes/no]: yes Router Self Signed Certificate successfully created
Note |
A router can have only one self-signed certificate. If you attempt to enroll a trustpoint configured for a self-signed certificate and one already exists, you receive a notification and are asked if you want to replace it. If so, a new self-signed certificate is generated to replace the existing one. |
Enabling the HTTPS Server Example
The following example shows how to enable the HTTPS server and generate a default trustpoint because one was not previously configured:
configure terminal Enter configuration commands, one per line. End with CNTL/Z. ip http secure-server % Generating 1024 bit RSA keys ...[OK] *Dec 21 19:14:15.421:%PKI-4-NOAUTOSAVE:Configuration was modified. Issue "write memory" to save new certificate Router(config)#
Note |
You need to save the configuration to NVRAM if you want to keep the self-signed certificate and have the HTTPS server enabled following router reloads. |
The following message also appears:
*Dec 21 19:14:10.441:%SSH-5-ENABLED:SSH 1.99 has been enabled
Note |
Creation of the key pair used with the self-signed certificate causes the Secure Shell (SSH) server to start. This behavior cannot be suppressed. You may want to modify your Access Control Lists (ACLs) to permit or deny SSH access to the router. You can use the ip ssh rsa keypair-name unexisting-key-pair-name command to disable the SSH server. |
Verifying the Self-Signed Certificate Configuration Example
The following example displays information about the self-signed certificate that you just created:
Router# show crypto pki certificates
Router Self-Signed Certificate
Status: Available
Certificate Serial Number: 01
Certificate Usage: General Purpose
Issuer:
cn=IOS-Self-Signed-Certificate-3326000105
Subject:
Name: IOS-Self-Signed-Certificate-3326000105
cn=IOS-Self-Signed-Certificate-3326000105
Validity Date:
start date: 19:14:14 GMT Dec 21 2004
end date: 00:00:00 GMT Jan 1 2020
Associated Trustpoints: TP-self-signed-3326000105
Note |
The number 3326000105 is the router's serial number and varies depending on the router's actual serial number. |
The following example displays information about the key pair corresponding to the self-signed certificate:
Router# show crypto key mypubkey rsa
% Key pair was generated at: 19:14:10 GMT Dec 21 2004
Key name: TP-self-signed-3326000105
Usage: General Purpose Key
Key is not exportable.
Key Data:
30819F30 0D06092A 864886F7 0D010101 05000381 8D003081 89028181 00B88F70
6BC78B6D 67D6CFF3 135C1D91 8F360292 CA44A032 5AC1A8FD 095E4865 F8C95A2B
BFD1C2B7 E64A3804 9BBD7326 207BD456 19BAB78B D075E78E 00D2560C B09289AE
6DECB8B0 6672FB3A 5CDAEE92 9D4C4F71 F3BCB269 214F6293 4BA8FABF 9486BCFC
2B941BCA 550999A7 2EFE12A5 6B7B669A 2D88AB77 39B38E0E AA23CB8C B7020301 0001
% Key pair was generated at: 19:14:13 GMT Dec 21 2004
Key name: TP-self-signed-3326000105.server
Usage: Encryption Key
Key is not exportable.
Key Data:
307C300D 06092A86 4886F70D 01010105 00036B00 30680261 00C5680E 89777B42
463E5783 FE96EA9E F446DC7B 70499AF3 EA266651 56EE29F4 5B003D93 2FC9F81D
8A46E12F 3FBAC2F3 046ED9DD C5F27C20 1BBA6B9B 08F16E45 C34D6337 F863D605
34E30F0E B4921BC5 DAC9EBBA 50C54AA0 BF551BDD 88453F50 61020301 0001
Note |
The second key pair with the name TP-self-signed-3326000105.server is the SSH key pair and is generated when any key pair is created on the router and SSH starts up. |
The following example displays information about the trustpoint named "local":
Router# show crypto pki trustpoints
Trustpoint local:
Subject Name:
serialNumber=C63EBBE9+ipaddress=10.3.0.18+hostname=test.example.com
Serial Number: 01
Persistent self-signed certificate trust point
Configuring Direct HTTP Enrollment Example
The following example show how to configure an enrollment profile for direct HTTP enrollment with a CA server:
crypto pki trustpoint Entrust enrollment profile E serial crypto pki profile enrollment E authentication url http://entrust:81 authentication command GET /certs/cacert.der enrollment url http://entrust:81/cda-cgi/clientcgi.exe enrollment command POST reference_number=$P2&authcode=$P1 &retrievedAs=rawDER&action=getServerCert&pkcs10Request=$REQ parameter 1 value aaaa-bbbb-cccc parameter 2 value 5001
Additional References
Related Documents
Related Topic |
Document Title |
---|---|
USB token RSA operations: Benefits of using USB tokens |
"Storing PKI Credentials" module in the Cisco IOS Security Configuration Guide: Secure Connectivity |
USB token RSA operations: Certificate server configuration |
"Configuring and Managing a Cisco IOS Certificate Server for PKI Deployment" chapter in the Cisco IOS Security Configuration Guide: Secure Connectivity See the "Generating a Certificate Server RSA Key Pair" section, the "Configuring a Certificate Server Trustpoint" section, and related examples. |
Overview of PKI, including RSA keys, certificate enrollment, and CAs |
" Cisco IOS PKI Overview: Understanding and Planning a PKI " module in the Cisco IOS Security Configuration Guide: Secure Connectivity |
Secure Device Provisioning: functionality overview and configuration tasks |
" Setting Up Secure Device Provisioning (SDP) for Enrollment in a PKI " module in the Cisco IOS Security Configuration Guide: Secure Connectivity |
RSA key generation and deployment |
" Deploying RSA Keys Within a PKI " module in the Cisco IOS Security Configuration Guide: Secure Connectivity |
Cisco IOS certificate server overview information and configuration tasks |
" Configuring and Managing a Cisco IOS Certificate Server for PKI Deployment " module in the Cisco IOS Security Configuration Guide: Secure Connectivity |
Setting up and using a USB token |
" Storing PKI Credentials " module in the Cisco IOS Security Configuration Guide: Secure Connectivity |
Cisco IOS security commands |
Cisco IOS Security Command Reference |
Suite-B ESP transforms |
Configuring Security for VPNs with IPsec feature module. |
Suite-B SHA-2 family (HMAC variant) and Elliptic Curve (EC) key pair configuration. |
Configuring Internet Key Exchange for IPsec VPNs feature module. |
Suite-B Integrity algorithm type transform configuration. |
Configuring Internet Key Exchange Version 2 (IKEv2) feature module. |
Suite-B Elliptic Curve Digital Signature Algorithm (ECDSA) signature (ECDSA-sig) authentication method configuration for IKEv2. |
Configuring Internet Key Exchange Version 2 (IKEv2) feature module. |
Suite-B Elliptic curve Diffie-Hellman (ECDH) support for IPsec SA negotiation |
Configuring Internet Key Exchange for IPsec VPNs and Configuring Internet Key Exchange Version 2 (IKEv2) feature modules. |
Recommended cryptographic algorithms |
MIBs
MIB |
MIBs Link |
---|---|
None. |
To locate and download MIBs for selected platforms, Cisco IOS releases, and feature sets, use Cisco MIB Locator found at the following URL: |
Technical Assistance
Description |
Link |
---|---|
The Cisco Support and Documentation website provides online resources to download documentation, software, and tools. Use these resources to install and configure the software and to troubleshoot and resolve technical issues with Cisco products and technologies. Access to most tools on the Cisco Support and Documentation website requires a Cisco.com user ID and password. |
Feature Information for PKI Certificate Enrollment
The following table provides release information about the feature or features described in this module. This table lists only the software release that introduced support for a given feature in a given software release train. Unless noted otherwise, subsequent releases of that software release train also support that feature.
Use Cisco Feature Navigator to find information about platform support and Cisco software image support. To access Cisco Feature Navigator, go to www.cisco.com/go/cfn. An account on Cisco.com is not required.
Table 1 | Feature Information for PKI Certificate Enrollment |
Feature Name |
Releases |
Feature Information |
||
---|---|---|---|---|
Cisco IOS USB Token PKI Enhancements--Phase 2 |
12.4(11)T |
This feature enhances USB token functionality by using the USB token as a cryptographic device. USB tokens may be used for RSA operations such as key generation, signing, and authentication. The following section provides information about this feature:
|
||
Certificate Authority Key Rollover |
12.4(2)T |
This feature introduces the ability for root CAs to roll over expiring CA certificates and keys and to have these changes propagate through the PKI network without manual intervention. The following sections provide information about this feature: The following commands were introduced or modified by this feature: auto-rollover, crypto pki certificate chain, crypto pki export pem, crypto pki server, crypto pki server info request, show crypto pki certificates, show crypto pki server, show crypto pki trustpoint. |
||
Certificate Autoenrollment |
12.2(8)T
|
This feature introduces certificate autoenrollment, which allows the router to automatically request a certificate from the CA that is using the parameters in the configuration. The following sections provide information about this feature: The following commands were introduced by this feature: auto-enroll, rsakeypair, show crypto ca timers. |
||
Certificate Enrollment Enhancements |
12.2(8)T
|
This feature introduces five new crypto ca trustpointcommands that provide new options for certificate requests and allow users to specify fields in the configuration instead of having to go through prompts. The following section provides information about this feature: The following commands were introduced by this feature: ip-address(ca-trustpoint), password(ca-trustpoint), serial-number, subject-name, usage. |
||
Direct HTTP Enrollment with CA Servers |
12.3(4)T
|
This feature allows users to configure an enrollment profile if their CA server does not support SCEP and they do not want to use an RA-mode CS. The enrollment profile allows users to send HTTP requests directly to the CA server instead of to an RA-mode CS. The following sections provide information about this feature:
The following commands were introduced by this feature: authentication command, authentication terminal, authentication url, crypto ca profile enrollment, enrollment command, enrollment profile, enrollment terminal, enrollment url, parameter. |
||
Import of RSA Key Pair and Certificates in PEM Format |
12.3(4)T |
This feature allows customers to issue certificate requests and receive issued certificates in PEM-formatted files. The following section provides information about this feature: The following commands were modified by this feature: enrollment, enrollment terminal. |
||
Key Rollover for Certificate Renewal |
12.3(7)T
|
This feature allows the certificate renewal request to be made before the certificate expires and retains the old key and certificate until the new certificate is available. The following sections provide information about this feature:
The following commands were introduced or modified by this feature: auto-enroll, regenerate. |
||
Manual Certificate Enrollment (TFTP Cut-and-Paste) |
12.2(13)T
|
This feature allows users to generate a certificate request and accept CA certificates and the router's certificates via a TFTP server or manual cut-and-paste operations. The following sections provide information about this feature: The following commands were introduced or modified by this feature: crypto ca import, enrollment, enrollment terminal. |
||
Multiple-Tier CA Hierarchy |
12.2(15)T |
This enhancement enables users to set up a PKI in a hierarchical framework to support multiple CAs. Within a hierarchical PKI, all enrolled peers can validate the certificate of one another as long as the peers share a trusted root CA certificate or a common subordinate CA. The following section provides information about this enhancement:
|
||
Persistent Self-Signed Certificates |
12.2(33)SXH 12.2(33)SRA 12.3(14)T
|
This feature allows the HTTPS server to generate and save a self-signed certificate in the router startup configuration. Thus, future SSL handshakes between the client and the HTTPS server can use the same self-signed certificate without user intervention. The following sections provide information about this feature:
The following commands were introduced or modified by this feature: enrollment selfsigned, show crypto pki certificates, show crypto pki trustpoints. |
||
PKI Status |
12.3(11)T |
This enhancement adds the status keyword to the show crypto pki trustpoints command, which allows you to display the current status of the trustpoint. Prior to this enhancement, you had to issue the show crypto pki certificates and the show crypto pki timers commands for the current status. The following section provides information about this enhancement:
|
||
Reenroll Using Existing Certificates |
12.3(11)T
|
This feature allows users to reenroll a router with a Cisco IOS CA via existing certificates from a third-party vendor CA. The following section provides information about this enhancement: The following commands were introduced by this feature: enrollment credential, grant auto trustpoint. |
||
Trustpoint CLI |
12.2(8)T |
This feature introduces the crypto pki trustpoint command, which adds support for trustpoint CAs. |
||
Suite-B support in IOS SW crypto |
15.1(2)T |
Suite-B adds the following support for certificate enrollment for a PKI:
Suite-B requirements comprise of four user interface suites of cryptographic algorithms for use with IKE and IPSec that are described in RFC 4869. Each suite consists of an encryption algorithm, a digital signature algorithm, a key agreement algorithm, and a hash or message digest algorithm. See the Configuring Security for VPNs with IPsec feature module for more detailed information about Cisco IOS Suite-B support. |
||
Public Key Infrastructure (PKI) IPv6 Support for VPN Solutions |
15.2(1)T |
The enrollment url (ca-trustpoint) command was modified to allow the specification of an IPv6 address in the URL for the CA. The ip-address (ca-trustpoint) command was modified to allow the specification of an IPv6 address that is included as "unstructuredAddress" in the certificate request. |
Cisco and the Cisco Logo are trademarks of Cisco Systems, Inc. and/or its affiliates in the U.S. and other countries. A listing of Cisco's trademarks can be found at www.cisco.com/go/trademarks . Third party trademarks mentioned are the property of their respective owners. The use of the word partner does not imply a partnership relationship between Cisco and any other company. (1005R)
Cisco and the Cisco logo are trademarks or registered trademarks of Cisco and/or its affiliates in the U.S. and other countries. To view a list of Cisco trademarks, go to this URL: www.cisco.com/go/trademarks. Third-party trademarks mentioned are the property of their respective owners. The use of the word partner does not imply a partnership relationship between Cisco and any other company. (1110R)
Any Internet Protocol (IP) addresses and phone numbers used in this document are not intended to be actual addresses and phone numbers. Any examples, command display output, network topology diagrams, and other figures included in the document are shown for illustrative purposes only. Any use of actual IP addresses or phone numbers in illustrative content is unintentional and coincidental.