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| cmake | ||
| conf | ||
| docs | ||
| goodies | ||
| inc | ||
| src | ||
| tests | ||
| .gitignore | ||
| .gitmodules | ||
| .travis.yml | ||
| ChangeLog.rst | ||
| CMakeLists.txt | ||
| LICENSE | ||
| README.rst | ||
uts-server
Micro RFC 3161 Time-Stamp server written in C.
- Doc
- Dev
- License
-
MIT
- Author
-
Pierre-Francois Carpentier - copyright © 2016
License
Released under the MIT Public License
What is RFC 3161?
An RFC 3161 time-stamp is basically a cryptographic signature with a date attached.
Roughly, it works as follow:
- A client application sends an hash of the data it wants to time-stamp to a Time-Stamp authority server.
- The Time-Stamp authority server retrieves the current date, concatenates it with the hash and uses its private key to create the time-stamp (kind of like a signature).
- The Time-Stamp authority server returns the generated time-stamp to the client application.
Then a client can verify the piece of data with the time-stamp using the Certificate Authority of the time-stamp key pair (X509 certificates).
It gives a cryptographic proof of a piece of data content, like a file, at a given time.
Some use cases:
- time-stamp log files at rotation time.
- time-stamp file at upload to prove it was delivered in due time or not.
Quick Start
# Building with civetweb embedded (will recover civetweb from github).
$ cmake . -DBUNDLE_CIVETWEB=ON
$ make
# Create some test certificates.
$ ./tests/cfg/pki/create_tsa_certs
# Launching the time-stamp server with test configuration in debug mode.
$ ./uts-server -c tests/cfg/uts-server.cnf -D
# In another shell, launching a time-stamp script on the README.md file.
$ ./goodies/timestamp-file.sh -i README.rst -u http://localhost:2020 -r -O "-cert";
# Verify the time-stamp.
$ openssl ts -verify -in README.rst.tsr -data README.rst -CAfile ./tests/cfg/pki/tsaca.pem
# Display the time-stamp content.
$ openssl ts -reply -in README.rst.tsr -textPowered by
