Chambersign
Sample code uses ES6 language features such as arrow functions and promises. For compatibility with IE11, code written with these features must be either transpiled using tools like Babel or refactored accordingly using callbacks
Chambersign introduction
The Chambersign token is a token that requires for the middleware of Chambersign to be installed prior to using it on the Trust1Connector.
Detect if Middleware has been installed.
Windows
The chambersign software for windows requires administration rights to be installed. After installation the location will be:
x64 & x86 ; C:\Program Files\ChamberSign
To check if this has been installed we can use the File-exchange create type function and then check the contents of the (sub)-folders.
To check if the middleware is installed the sample code below is a good start to use the File-Exchange to check if the middleware has been installed and its safe to continue to use the ChamberSign middleware and the Trust1Connector.
This is an example of how this could be integrated. You are free to implement this however you like. Information for the file-exchange module can be found here
Interface
Be aware that for chambersign only the following functions are supported at this time:
authenticate
sign
verifyPin
AuthenticationCertificate
NonRepudiationCertificate
AllCerts(auth, nonrep)
allAlgoRefs
resetBulkPin
Models
All model information can be found in the Token typings model page
Initialise the Trust1Connector JS
Initialise a Trust1Connector client with a valid configuration:
Obtain the Reader information
In order to get all connected card-readers, with available cards:
This function call returns:
Using the generic interface can be done as follows;
Because we're using the generic interface we can define the module variable upfront since we know we want to use the chambersign integration.
Certificates
Exposes all the certificates publicly available on the smart card.
Authentication Certificate
Contains the 'authentication certificate' stored on the smart card. The 'authentication certificate' contains the public key corresponding to the private RSA authentication key. The 'authentication certificate' is needed for pin validation and authentication. When additional parsing of the certificate is needed you can add a boolean to indicate if you want to parse the certificate or not The service can be called:
Response:
Non-repudiation Certificate
Contains the 'non-repudiation certificate' stored on the smart card. The 'non-repudiation certificate' contains the public key corresponding the private RSA non-repudiation key. When additional parsing of the certificate is needed you can add a boolean to indicate if you want to parse the certificate or not The service can be called:
Response:
Filter Certificates
All certificates on the smart card can be dumped at once, or using a filter. In order to read all certificates at once:
Response:
The filter can be used to ask a list of custom data containers. For example, we want to read only the rootCertificate
Response:
Sign Data
To get the certificates necessary for signature validation in your back-end:
Response:
Depending on the connected smart card reader. A sign can be executed in 2 modes:
Using a connected card reader with 'pin-pad' capabilities (keypad and display available)
Using a connected card reader without 'pin-pad' capabilities (no keypad nor display available)
Security consideration: In order to sign a hash, security considerations prefer using a 'pin-pad'.
Sign Hash without pin-pad
When the web or native application is responsible for showing the password input, the following request is used to sign a given hash:
Response is a base64 encoded signed hash:
The 'authenticationreference' property can contain the following values: sha1, sha256, sha512, md5.
Sign Hash with pin-pad
When the pin entry is done on the pin-pad, the following request is used to sign a given hash:
Response is a base64 encoded signed hash:
The 'algorithm_reference' property can contain the following values: sha1, sha256, sha512, md5.
The core services lists connected readers, and if they have pin-pad capability. You can find more information in the Core Service documentation on how to verify card reader capabilities.
Bulk Signing
It is possible to bulk sign data without having to re-enter the PIN by adding an optional bulk
parameter set to true
to the request. Subsequent sign requests will not require the PIN to be re-entered until a request with bulk
being set to false
is sent, or the Bulk Sign Reset method is called.
When using bulk signing, great care must be taken to validate that the first signature request was successful prior to sending subsequent requests. Failing to do this will likely result in the card being blocked.
Bulk PIN Reset
The PIN set for bulk signing can be reset by calling this method.
Response will look like:
Verify PIN
Verify PIN without pin-pad
When the web or native application is responsible for showing the password input, the following request is used to verify a card holder PIN:
Response:
Verify PIN with pin-pad
When the pin entry is done on the pin-pad, the following request is used to verify a given PIN:
Response:
Authentication
The T1C-GCL is able to authenticate a card holder based on a challenge. The challenge can be:
provided by an external service
provided by the smart card An authentication can be interpreted as a signature use case, the challenge is signed data, that can be validated in a back-end process.
External Challenge
An external challenge is provided in the data property of the following example:
Response:
Take notice that the PIN property can be omitted when using a smart card reader with pin-pad capabilities.
Get valid algorithms to use for Sign or Authenticate
Via the Trust1Connector generic modules you are able to retrieve available algorithms to use for Signing or Authenticate
The response you can expect is a list of algorithms, an example can be found below (the values below are purely examplatory)
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