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208 lines
9.9 KiB
Markdown
208 lines
9.9 KiB
Markdown
## Sane Recommendations
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TLS, PKI, X509, HTTPS, etc. all require configuration. All of
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these technologies allow the user to "shoot themselves in the foot" by
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misconfiguring them and reducing their benefits significantly. Therefore,
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offering an easy to use solution that works out of the box means choosing and
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enforcing sane default configurations for all these technologies.
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Below we document some of the significant default configuration that we recommend.
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This document is a moving target: security and cryptography are constanly
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changing and evolving - vulnerabilities are found, new algorithms are created,
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etc. We inted for this document be an accurate representation of current
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best practices in the industry, and to have these practices codified as defaults
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in the `certificates` code base. If you have questions, suggestions, or comments
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about any of these decisions please let us know.
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### Tokens
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We use JWTs (JSON Web Tokens to prove authenticity and identity within the Step
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ecosystem. JWTs have received negative attention because they are easy to
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misuse, misconfigure.
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We agree! But lots of things are easy to misuse. We also believe
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that when configured well JWTs are a great way to sign and encode data. Our JWT's
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are, by default, short-lived (5 minute lifespan) and can only be used once during
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the lifetime of the Step CA. We use a 1 minute clock drift leeway because that
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was the recommended default in the reputable JWT package that we chose. If using
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Step JWTs or your own JWTs in your code be sure to verify and validate every
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single standard attributed of the JWT. JWTs, like all cryptographic tools,
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are useless without proper attention to configuration and guidelines.
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### Keys
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```
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// RSA keys don't scale very well. To get 128 bits of security, you need 3,072-bit
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// RSA keys, which are noticeably slower. ECDSA keys provide an alternative
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// that offers better security and better performance. At 256 bits, ECDSA keys
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// provide 128 bits of security. A small number of older clients don't support
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// ECDSA, but most modern clients do.
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Default Key Type: ECDSA
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Default Curve Bits: P-256
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// Encryption algorithm for writing private keys to disk. We've chosen AES
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// (aka Rijndael) because it was the official choice of the Advanced Encryption
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// Standard contest. The three supported key sizes are 128, 192, and 256. Each
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// of these is considered to be unbreakable for the forseeable future, therefore
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// we chose 128 bits as our default because the performance is better
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// (as compared to the greater key sizes) and because we agree, with the
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// designers of the algorithm, that 128 bits are quite sufficient for most
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// security needs.
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Default PEMCipher: AES128
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```
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### X.509 Certificate Defaults
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* **root certificate**
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```
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* Validity (10 year window)
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* Not Before: Now
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// A 10 year window seems advisable until software and tools can be written
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// for rotating the root certificate.
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* Not After: Now + 10 years
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* Basic Constraints
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// The root certificate is a Certificate Authority, it will be used to sign
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// other Certificates.
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* CA: TRUE
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// The path length constraint expresses the number of possible intermediate
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// CA certificates in a path built from an end-entity certificate up to the
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// CA certificate. An absent path length constraint means that there is no
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// limitation to the number of intermediate certificates from end-entity to
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// the CA certificate. The smallstep PKI has only one intermediate CA
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//certificate between end-entity certificates and the root CA certificcate.
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* pathlen: 1
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* Key Usage // Describes how the keys can be used.
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// Indicates that a certificate will be used with a protocol that encrypts keys.
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* Key Encipherment
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// Indicates that our root public key will be used to verify a signature on
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// certificates.
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* Certificate Signing
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// Indicates that our root public key will be used to verify a signature on
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// revocation
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// information, such as CRL.
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* CRL Sign
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// Indicates that our root public key may be used as a digital signature to
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// support security services that enable entity authentication and data
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// origin authentication with integrity.
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* Digital Signature
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```
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* **intermediate certificate**
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```
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* Validity (10 year window)
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* Not Before: Now
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// A 10 year window seems advisable until software and tools can be written
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// for rotating the intermediates certificates without considerable agony
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// on the part of the user.
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* Not After: Now + 10 years
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* Basic Constraints
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// The intermediate certificate is a Certificate Authority, used to sign
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// end-entity (service, process, job, etc.) certificates.
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* CA: TRUE
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// The path length constraint expresses the number of possible intermediate
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// CA certificates in a path built from an end-entity certificate up to the
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// CA certificate. An absent path length constraint means that there is no
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// limitation to the number of intermediate certificates from end-entity to
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// the CA certificate. There are no additional intermediary certificates in
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// the path between the smallstep intermediate CA and end-entity certificates.
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* pathlen: 0
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* Key Usage
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// Indicates that a certificate will be used with a protocol that encrypts keys.
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* Key Encipherment
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// Indicates that our root public key will be used to verify a signature on
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// certificates.
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* Certificate Signing
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// Indicates that this public key can be used to verify a signature on
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// revocation information, such as CRL.
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* CRL Sign
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// Indicates that this public key may be used as a digital signature to
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// support security services that enable entity authentication and data
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// origin authentication with integrity.
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* Digital Signature
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* Extended Key Usage
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// Certificate can be used as the server side certificate in the TLS protocol.
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* TLS Web Server Authentication
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// Certificate can be used as the client side certificate in the TLS protocol.
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* TLS Web Client Authentication
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```
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* **Leaf Certificate - End Entity Certificate** (certificates returned by the CA)
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```
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* Validity (24 hour window)
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* Not Before: Now
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// The default is a 24hr window. This value is somewhat arbitrary, however,
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// our goal is to have seamless end-entity certificate rotation (we are
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// getting close). Rotating certificates frequently is good security hygiene
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// because it gives bad actors very little time to form an attack and limits
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// the usefulness of any single private key in the system. We will continue
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// to work towards decreasing this window because we believe it significantly
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// reduces probability and effectiveness of any attack.
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* Not After: Now + 24 hours
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* Key Usage
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// Indicates that a certificate will be used with a protocol that encrypts keys.
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* Key Encipherment
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// Indicates that this public key may be used as a digital signature to
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// support security services that enable entity authentication and data
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// origin authentication with integrity.
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* Digital Signature
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* Extended Key Usage
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// Certificate can be used as the server side certificate in the TLS protocol.
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* TLS Web Server Authentication
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// Certificate can be used as the client side certificate in the TLS protocol.
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* TLS Web Client Authentication
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```
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### Default TLS Configuration Options
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```
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// The PCI Security Standards Council is requiring all payment processors
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// and merchants to move to TLS 1.2 and above by June 30, 2018. By setting
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// TLS 1.2 as the default for all tls protocol negotiation we encourage our
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// users to adopt the same security conventions.
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* MinVersion: TLS 1.2
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* MaxVersion: TLS 1.2
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// https://github.com/ssllabs/research/wiki/SSL-and-TLS-Deployment-Best-Practices#23-use-secure-cipher-suites
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// The default 'ciphersuites' is a single cipher combination. For communication
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// between services running step there is no need for cipher suite negotiation.
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// The server can specify a single cipher suite which the client is already
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// known to support. Reasons for selecting "TLS_ECDHE_ECDSA_WITH_CHACHA20_POLY1305":
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// - ECDHE key exchange algorithm has perfect forward secrecy
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// - ECDSA has smaller keys and better performance (than RSA)
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// - CHACHA20 with POLY1305 is the cipher mode used by google.
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// - CHACHA20's performance is better than GCM and CBC.
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// NOTE: The http2 spec requires the "TLS_ECDHE_(RSA|ECDSA)_WITH_AES_128_GCM_SHA256"
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// ciphersuite be accepted by the server, therefore it makes our list of
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// default ciphersuites until we build the functionality to modify our defaults
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// based on http version.
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* DefaultCipherSuites: [
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"TLS_ECDHE_ECDSA_WITH_CHACHA20_POLY1305",
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"TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256",
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]
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// The following is a list of step approved cipher suites. Not all communication
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// can be mediated with step TLS functionality. For those connections the list of
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// server supported cipher suites must have more options - in case older clients
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// do not support our favored cipher suite. Reasons for selecting these cipher
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// suites can be found in the ssllabs article cited above.
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* ApprovedCipherSuites: [
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"TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA",
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"TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA256",
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"TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256",
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"TLS_ECDHE_ECDSA_WITH_AES_256_CBC_SHA",
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"TLS_ECDHE_ECDSA_WITH_AES_256_GCM_SHA384",
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"TLS_ECDHE_ECDSA_WITH_CHACHA20_POLY1305",
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"TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA",
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"TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA256",
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"TLS_ECDHE_RSA_WITH_AES_128_GCM_SHA256",
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"TLS_ECDHE_RSA_WITH_AES_256_CBC_SHA",
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"TLS_ECDHE_RSA_WITH_AES_256_GCM_SHA384",
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"TLS_ECDHE_RSA_WITH_CHACHA20_POLY1305",
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]
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// TLS renegotiation significantly complicates the state machine and has been
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// the source of numerous, subtle security issues. Therefore, by default we
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// disable it.
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* Renegotation: Never
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