I have a simple chain setup and can successfully verify in this case:
$ openssl version
OpenSSL 1.0.2m 2 Nov 2017
$ openssl verify -CAfile chain.pem cert.pem
cert.pem: OK
However I get errors in these cases:
$ openssl verify -CAfile ca-cert.pem cert.pem
cert.pem: C = US...
error 2 at 1 depth lookup:unable to get issuer certificate
Specifically the unable to get issuer certificate.
Also get it here:
$ openssl verify chain.pem
chain.pem: C = US...
error 20 at 0 depth lookup:unable to get local issuer certificate
$ openssl verify cert.pem
cert.pem: C...
error 20 at 0 depth lookup:unable to get local issuer certificate
Finally, I get it in Node.js when I pass the keys to an HTTPS server:
events.js:193
throw er; // Unhandled 'error' event
^
Error: unable to get local issuer certificate
at TLSSocket.onConnectSecure (_tls_wrap.js:1036:34)
at emitNone (events.js:115:13)
at TLSSocket.emit (events.js:218:7)
at TLSSocket._finishInit (_tls_wrap.js:637:8)
I tried passing it with { key, cert, ca }
, but still same error.
Wondering how to go about debugging this or what the fix is to get an HTTPS server running.
If I use a pfx
file I get the following:
events.js:193
throw er; // Unhandled 'error' event
^
Error: self signed certificate in certificate chain
at TLSSocket.onConnectSecure (_tls_wrap.js:1036:34)
at emitNone (events.js:115:13)
at TLSSocket.emit (events.js:218:7)
at TLSSocket._finishInit (_tls_wrap.js:637:8)
If I leave only the cert.pem in the cert file, and make the ca
attribute be the ca-cert.pem, it gives:
Error: unable to verify the first certificate
at TLSSocket.<anonymous> (_tls_wrap.js:1108:38)
at emitNone (events.js:105:13)
at TLSSocket.emit (events.js:207:7)
at TLSSocket._finishInit (_tls_wrap.js:638:8)
at TLSWrap.ssl.onhandshakedone (_tls_wrap.js:468:38)
Not sure what to do.
Here they say:
OpenSSL is unable to find a local certificate for the issuer (or the issuer of the first certificate in the chain received from the web server during the TLS handshake) with which to verify the signature(s).
Not sure what that means.
This error means the certificate path or chain is broken and you are missing certificate files.
-
https://wiki.zimbra.com/wiki/Fix_depth_lookup:unable_to_get_issuer_certificate
Update
Slightly more help:
This problem is usually indicated by log messages saying something like "unable to get local issuer certificate" or "self signed certificate". When a certificate is verified its root CA must be "trusted" by OpenSSL this typically means that the CA certificate must be placed in a directory or file and the relevant program configured to read it. The OpenSSL program 'verify' behaves in a similar way and issues similar error messages: check the verify(1) program manual page for more information.
- https://www.openssl.org/docs/faq.html#USER6
But still doesn't help very much.
Looks like Node.js is using a 1.0.2l instead of 1.0.2m but doesn't seem like a big deal.
$ node -pe process.versions | grep openssl
openssl: '1.0.2l'
Update 2
Weird, I get this when I make a request from Node.js:
Uncaught Error: unable to verify the first certificate
at TLSSocket.onConnectSecure (_tls_wrap.js:1036:34)
at TLSSocket._finishInit (_tls_wrap.js:637:8)
But when I go to the browser, I don't see the "Proceed with caution" page, and can successfully log a request in Node.js. Maybe that helps somewhat. Please help :D
(This answer extracted from X509_verify_cert
at crypto/x509/x509_vfy.c:204
, in openssl-1.0.2m)
The OpenSSL verify
application verifies a certificate in the following way: It builds the certificate chain starting with the target certificate, and tracing the issuer chain, searching any untrusted certificates supplied along with the target cert first. Upon failing to find an untrusted issuer cert, OpenSSL switches to the trusted certificate store and continues building the chain. This process stops when
- an issuer is not found in the trusted store.
- a self-signed certificate is encountered.
- the max-verify depth is encountered.
At this point we have a chain that may end prematurely (if we failed to find an issuer, or if we exceeded the verify depth).
OpenSSL then scans over each trusted certificate on the chain looking for SSLv3 extensions that specify the purpose of the trusted certificate. If the trusted certificate has the right "trust" attributes for the "purpose" of the verification operation (or has the anyExtendedKeyUsage
attribute) the chain is trusted. (Forgive the hand-wave on trust attributes, that part of the code was difficult to read.)
So lets test it out. First, let's repro the OP's error cases:
#
echo "Making Root CA..."
openssl req -newkey rsa:4096 -nodes -keyout ca-key.pem -sha384 -x509 -days 365 -out ca-crt.pem -subj /C=XX/ST=YY/O=RootCA
echo "Making Intermediate CA..."
openssl req -newkey rsa:3072 -nodes -keyout int-key.pem -new -sha384 -out int-csr.pem -subj /C=XX/ST=YY/O=IntermediateCA
openssl x509 -req -days 360 -in int-csr.pem -CA ca-crt.pem -CAkey ca-key.pem -CAcreateserial -out int-crt.pem
echo "Making User Cert..."
openssl req -newkey rsa:2048 -nodes -keyout usr-key.pem -new -sha256 -out usr-csr.pem -subj /C=XX/ST=YY/O=LockCmpXchg8b
openssl x509 -req -days 360 -in usr-csr.pem -CA int-crt.pem -CAkey int-key.pem -CAcreateserial -out usr-crt.pem
echo ""
echo "Making Chain..."
cat ca-crt.pem int-crt.pem > chain.pem
echo ""
echo "Verfying UserCert via RootCA..."
openssl verify -CAfile ca-crt.pem usr-crt.pem
echo ""
echo "Verfying UserCert via IntermediateCA..."
openssl verify -CAfile int-crt.pem usr-crt.pem
echo ""
echo "Verfying UserCert via chain..."
openssl verify -CAfile chain.pem usr-crt.pem
yields
[... Skipping OpenSSL KeyGen / CertGen verbosity ...]
Making Chain...
Verfying UserCert via RootCA...
usr-crt.pem: C = XX, ST = YY, O = LockCmpXchg8b
error 20 at 0 depth lookup:unable to get local issuer certificate
Verfying UserCert via IntermediateCA...
usr-crt.pem: C = XX, ST = YY, O = IntermediateCA
error 2 at 1 depth lookup:unable to get issuer certificate
Verfying UserCert via chain...
usr-crt.pem: OK
Now, lets use the -addtrust
option of openssl x509
to make sure we have one of the acceptable trust attributes on the intermediate CA (call this one IntermediateCAWithTrust
; we'll use it to sign AnotherUserCert
.):
echo ""
echo "Alternate Intermedate CA (using -addtrust anyExtendedKeyUsage)"
echo ""
echo "Making IntermediateCAWithTrust..."
openssl req -newkey rsa:3072 -nodes -keyout int-key2.pem -new -sha384 -out int-csr2.pem -subj /C=XX/ST=YY/O=IntermediateCAWithTrust
openssl x509 -req -days 360 -in int-csr2.pem -CA ca-crt.pem -CAkey ca-key.pem -CAcreateserial -out int-crt2.pem -addtrust anyExtendedKeyUsage
echo "Making AnotherUser Cert..."
openssl req -newkey rsa:2048 -nodes -keyout usr-key2.pem -new -sha256 -out usr-csr2.pem -subj /C=XX/ST=YY/O=LockCmpXchg8b_2
openssl x509 -req -days 360 -in usr-csr2.pem -CA int-crt2.pem -CAkey int-key2.pem -CAcreateserial -out usr-crt2.pem
echo ""
echo "Verfying AnotherUserCert via IntermediateCAWithTrust..."
openssl verify -CAfile int-crt2.pem usr-crt2.pem
This yields
Alternate Intermedate CA (using -addtrust anyExtendedKeyUsage)
Making IntermediateCAWithTrust...
[... Snip more OpenSSL generation output ...]
Making AnotherUser Cert...
[... Snip more OpenSSL generation output ...]
Verfying AnotherUserCert via IntermediateCAWithTrust...
usr-crt2.pem: OK
Hey look! we just successfully verified AnotherUserCert via the IntermediateCAWithTrust, even though we didn't supply the whole chain. The key to this difference is that any one of the trusted certificates in the chain had an appropriate trust attribute for the verify operation.
Looking a little closer (via openssl x509 -in ca-crt.pem -noout -text
), our CA certificate has
X509v3 Basic Constraints:
CA:TRUE
which I would imagine OpenSSL treats as a general "may verify for any purpose" extension. The new IntermediateCAWithTrust
does not have X509v3 Basic Constraints
, but instead has
Trusted Uses:
Any Extended Key Usage
No Rejected Uses.
For more info in the -addtrust
option, and the types of trust attributes that can be added, see https://www.openssl.org/docs/manmaster/man1/x509.html#TRUST_SETTINGS
Near the bottom of that page is a concise summary of the preceding discussion:
The basicConstraints extension CA flag is used to determine whether
the certificate can be used as a CA. If the CA flag is true then it is
a CA, if the CA flag is false then it is not a CA. All CAs should have
the CA flag set to true.
If the basicConstraints extension is absent then the certificate is
considered to be a "possible CA" other extensions are checked
according to the intended use of the certificate. A warning is given
in this case because the certificate should really not be regarded as
a CA: however it is allowed to be a CA to work around some broken
software.
So, in short, make sure your intermediate CAs are properly CAs (in their X509v3 Basic Constraints
). This seems an excellent tutorial (and it explicitly generates the intermediate CA as a CA): https://jamielinux.com/docs/openssl-certificate-authority/create-the-root-pair.html
As a backup plan, you can always supply the whole chain, or you can make your intermediate CAs with the -addtrust
hack.
https://letsencrypt.org/ is really easy to use and free. Also, run node without SSL on a local HTTP port and use NGINX as a HTTPS proxy.
sudo apt-get install certbot nginx
server {
listen 80 default_server;
listen [::]:80 default_server;
server_name _;
return 301 https://$host$request_uri;
}
server {
listen 443 ssl default_server;
listen [::]:443 ssl default_server;
ssl on;
ssl_certificate /etc/letsencrypt/live/host.com/fullchain.pem;
ssl_certificate_key /etc/letsencrypt/live/host.com/privkey.pem;
access_log /var/log/nginx/host.access.log;
error_log /var/log/nginx/host.error.log;
server_name _;
gzip on;
gzip_proxied any;
gzip_types text/css text/javascript text/xml text/plain application/javascript application/x-javascript application/json;
location / {
include /etc/nginx/proxy_params;
proxy_pass http://localhost:8080;
proxy_read_timeout 90s;
proxy_redirect http://localhost:8080 https://www.host.com;
}
}