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I'm adding https support to an embedded linux device. I have tried to generate a self-signed certificate with these steps:

openssl req -new > cert.csr
openssl rsa -in privkey.pem -out key.pem
openssl x509 -in cert.csr -out cert.pem -req -signkey key.pem -days 1001
cat key.pem>>cert.pem

This works, but I get some errors with, for example, google chrome:

This is probably not the site you are looking for!
The site's security certificate is not trusted!

Am I missing something? Is this the correct way to build a self-signed certificate?

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8  
Self-signed certificates are considered insecure for the Internet. Firefox will treat the site as having an invalid certificate, while Chrome will act as if the connection was plain HTTP. More details: gerv.net/security/self-signed-certs –  user1202136 Apr 16 '12 at 14:17
5  
You need to import your CA certificate into your browsers and tell the browsers you trust the certificate -or- get it signed by one of the big money-for-nothing organizations that are already trusted by the browsers -or- ignore the warning and click past it. I like the last option myself. –  trojanfoe Apr 16 '12 at 14:20
5  
IMO this belongs to ServerFault! –  KurzedMetal Apr 16 '12 at 14:26
3  
IMO, it's fine here. Although the original context was a server, and that's the most common use, it is not at all specific to servers. Certs are used for many other purposes. Of course, reminding the OP of the existence of ServerFault is a good thing. :) –  Bob Kerns Jan 31 '14 at 21:26
1  
Clicking past warnings as @trojanfoe is fine, if you don't mind being MitMed. –  Fixee Jul 12 '14 at 22:25

4 Answers 4

up vote 289 down vote accepted

You can do that in one command:

openssl req -x509 -newkey rsa:2048 -keyout key.pem -out cert.pem -days XXX

You can add -nodes if you don't want to protect your private key with a passphrase.

Self-signed certs are not validated with any third party unless you import them to the browsers previously. If you need more security, you should use a certificate signed by a CA.

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2  
how do you do this without requiring a password on the cert? anytime i restart my web server i am required to provide a password. annoying! –  the0ther Apr 28 '13 at 1:07
31  
@the0ther read the sentence just below the command :) –  diegows Apr 29 '13 at 20:43
1  
Does this support a wildcard? –  Cerin Nov 11 '13 at 17:45
2  
Yes, but because is a self-signed certificado, doesn't make any sense usually :) –  diegows Nov 15 '13 at 18:09
5  
Add -subj '/CN=localhost' to suppress questions about the contents of the certificate (replace localhost with your desired domain). –  Rob W Jun 20 '14 at 21:57

Here are the options described in @diegows's answer, described in more detail, from the documentation:

openssl req -x509 -newkey rsa:2048 -keyout key.pem -out cert.pem -days XXX
req

PKCS#10 certificate request and certificate generating utility.

-x509

this option outputs a self signed certificate instead of a certificate request. This is typically used to generate a test certificate or a self signed root CA.

-newkey arg

this option creates a new certificate request and a new private key. The argument takes one of several forms. rsa:nbits, where nbits is the number of bits, generates an RSA key nbits in size.

-keyout filename

this gives the filename to write the newly created private key to.

-out filename

This specifies the output filename to write to or standard output by default.

-days n

when the -x509 option is being used this specifies the number of days to certify the certificate for. The default is 30 days.

-nodes

if this option is specified then if a private key is created it will not be encrypted.

The documentation is actually more detailed than the above, I just summarized it here.

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Am I missing something? Is this the correct way to build a self-signed certificate?

Its easy to create a self signed certificate. You just use the openssl req command. It can be tricky to create one that can be consumed by the largest selection of clients, like browsers and command line tools.

Its difficult because the browsers have their own set of requirements, and they are more restrictive than the IETF. The requirements used by browsers are documented at the CA/Browser Forums (see references below). The restrictions arise in two key areas: (1) trust anchors, and (2) DNS names.

Modern browsers (like the warez we're using in 2014/2015) want a certificate that chains back to a trust anchor, and they want DNS names to be presented in particular ways in the certificate. And Browsers are actively moving against self signed server certificates

Some browsers don't exactly make it easy to import a self signed server certificate. In fact, you can't with some browsers, like Android's browser. So the complete solution is to become your own authority.

In the absence of becoming your own authority, you have to get the DNS names right to give the certificate the greatest chance of success. But I would encourage you to become your own authority. Its easy to become your own authority and it will side step all the trust issues (who better to trust than yourself?).

----------

This is probably not the site you are looking for!
The site's security certificate is not trusted!

This is because browsers use a predefined list of trust anchors to validate server certificates. A self signed certificate does not chain back to a trusted anchor.

The best way to avoid this is:

  1. Create your own authority (i.e, become a CA)
  2. Create a certificate signing request (CSR) for the server
  3. Sign the server's CSR with your CA key
  4. Install the server certificate on the server
  5. Install the CA certificate on the client

Step 1 - Create your own authority just means to create a self signed certificate with CA: true and proper key usage. That means the Subject and Issuer are the same entity, CA is set to true in Basic Constraints (it should also be marked as critical), key usage is keyCertSign and crlSign (if you are using CRLs), and the Subject Key Identifier (SKI) is the same as the Authority Key Identifier (AKI).

Steps 2 - 4 are roughly what you do now for a public facing server when you enlist the services of a CA like Startcom or CAcert. Steps 1 and 5 allows you to avoid the third party authority, and act as your own authority (who better to trust than yourself?).

The next best way to avoid the browser warning is to trust the server's certificate. But some browsers, like Android's default browser, do not let you do it. So it will never work on the platform.

The issue of browsers (and other similar user agents) not trusting self signed certificates is going to be a big problem in the Internet of Things (IoT). For example, what is going to happen when you connect to your thermostat or refrigerator to program it? The answer is, nothing good as far as the user experience is concerned.

The W3C's WebAppSec Working Group is starting to look at the issue. See, for example, Proposal: Marking HTTP As Non-Secure.

You might also be interested in Getting Chrome to accept self-signed localhost certificate.


How to create a self-signed certificate with openssl?

The commands below and the configuration file create a self signed certificate (it also shows you how to create a signing request). They differ from other answers in one respect: the DNS names used for the self signed certificate are in the Subject Alternate Name (SAN), and not the Common Name (CN).

The DNS names are placed in the SAN through the configuration file with the line subjectAltName = @alternate_names (there's no way to do it through the command line). Then there's an alternate_names section in the configuration file (you should tune this to suit your taste):

[ alternate_names ]

DNS.1       = example.com
DNS.2       = www.example.com
DNS.3       = mail.example.com
DNS.4       = ftp.example.com

# Add these if you need them. But usually you don't want them or
#   need them in production. You may need them for development.
# DNS.5       = localhost
# DNS.6       = localhost.localdomain
# DNS.7       = 127.0.0.1

# IPv6 localhost
# DNS.8     = ::1

Its important to put DNS name in the SAN and not the CN because both the IETF and the CA/Browser Forums specify the practice. They also specify that DNS names in the CN are deprecated (but not prohibited). If you put a DNS name in the CN, then it must be included in the SAN under the CA/B policies. So you can't avoid using the Subject Alternate Name.

If you don't do put DNS names in the SAN, then the certificate will fail to validate under a browser and other user agents which follow the CA/Browser Forum guidelines.

Related: browsers follow the CA/Browser Forum policies; and not the IETF policies. That's one of the reasons a certificate created with OpenSSL (which generally follows the IETF) sometimes does not validate under a Browser (browsers follow the CA/B). They are different standards, they have different issuing policies and different validation requirements.


Create a self signed certificate (notice the addition of -x509 option):

openssl req -config example-com.conf -new -x509 -sha256 -newkey rsa:2048 -nodes \
    -keyout example-com.key.pem -days 365 -out example-com.cert.pem

Create a signing request (notice the lack of -x509 option):

openssl req -config example-com.conf -new -newkey rsa:2048 -nodes \
    -keyout example-com.key.pem -days 365 -out example-com.req.pem

Print a self signed certificate:

openssl x509 -in example-com.cert.pem -text -noout

Print a signing request:

openssl req -in example-com.req.pem -text -noout

Configuration file (passed via -config option)

[ req ]
default_bits        = 2048
default_keyfile     = server-key.pem
distinguished_name  = subject
req_extensions      = req_ext
x509_extensions     = x509_ext
string_mask         = utf8only

# The Subject DN can be formed using X501 or RFC 4514 (see RFC 4519 for a description).
#   Its sort of a mashup. For example, RFC 4514 does not provide emailAddress.
[ subject ]
countryName         = Country Name (2 letter code)
countryName_default     = US

stateOrProvinceName     = State or Province Name (full name)
stateOrProvinceName_default = NY

localityName            = Locality Name (eg, city)
localityName_default        = New York

organizationName         = Organization Name (eg, company)
organizationName_default    = Example, LLC

# Use a friendly name here because its presented to the user. The server's DNS
#   names are placed in Subject Alternate Names. Plus, DNS names here is deprecated
#   by both IETF and CA/Browser Forums. If you place a DNS name here, then you 
#   must include the DNS name in the SAN too (otherwise, Chrome and others that
#   strictly follow the CA/Browser Baseline Requirements will fail).
commonName          = Common Name (e.g. server FQDN or YOUR name)
commonName_default      = Example Company

emailAddress            = Email Address
emailAddress_default        = test@example.com

# Section x509_ext is used when generating a self-signed certificate. I.e., openssl req -x509 ...
[ x509_ext ]

subjectKeyIdentifier        = hash
authorityKeyIdentifier  = keyid,issuer

basicConstraints        = CA:FALSE
keyUsage            = digitalSignature, keyEncipherment
subjectAltName          = @alternate_names
nsComment           = "OpenSSL Generated Certificate"

# RFC 5280, Section 4.2.1.12 makes EKU optional
# CA/Browser Baseline Requirements, Appendix (B)(3)(G) makes me confused
# extendedKeyUsage  = serverAuth, clientAuth

# Section req_ext is used when generating a certificate signing request. I.e., openssl req ...
[ req_ext ]

subjectKeyIdentifier        = hash

basicConstraints        = CA:FALSE
keyUsage            = digitalSignature, keyEncipherment
subjectAltName          = @alternate_names
nsComment           = "OpenSSL Generated Certificate"

# RFC 5280, Section 4.2.1.12 makes EKU optional
# CA/Browser Baseline Requirements, Appendix (B)(3)(G) makes me confused
# extendedKeyUsage  = serverAuth, clientAuth

[ alternate_names ]

DNS.1       = example.com
DNS.2       = www.example.com
DNS.3       = mail.example.com
DNS.4       = ftp.example.com

# Add these if you need them. But usually you don't want them or
#   need them in production. You may need them for development.
# DNS.5       = localhost
# DNS.6       = localhost.localdomain
# DNS.7       = 127.0.0.1

# IPv6 localhost
# DNS.8     = ::1

Related: there are other rules concerning the handling of DNS names in X.509/PKIX certificates. Refer to these documents for the rules:

RFC 6797 is listed because its more restrictive than the other RFCs and CA/B documents. RFC 6797 does not allow an IP address, either.

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I would recommend to add -sha256 parameter, to use SHA-2 hash algorithm, because major browsers are considering to show "SHA-1 certificates" as not secure.

The same command line from the accepted answer - @diegows with added -sha256

openssl req -x509 -sha256 -newkey rsa:2048 -keyout key.pem -out cert.pem -days XXX

More info in Google Security blog.

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If it's a self signed key, it's going to generate browser errors anyway, so this doesn't really matter –  Mark Dec 16 '14 at 13:43
5  
@Mark, it matters, because SHA-2 is more secure –  Maris B. Dec 17 '14 at 15:38
    
Opening the certificate in windows after renaming the cert.pem to cert.cer says the fingerprint algorithm still is Sha1, but the signature hash algorithm is sha256. –  sinned Dec 19 '14 at 8:33
    
This does not provide an answer to the question. To critique or request clarification from an author, leave a comment below their post. –  Mureinik Jan 13 at 21:41

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