ADR 050: SIGN_MODE_TEXTUAL: Annex 2 XXX
- Oct 3, 2022: Initial Draft
This annex provides normative guidance on how devices should render a
SIGN_MODE_TEXTUAL allows a legible version of a transaction to be signed
on a hardware security device, such as a Ledger. Early versions of the
design rendered transactions directly to lines of ASCII text, but this
proved awkward from its in-band signaling, and for the need to display
Unicode text within the transaction.
SIGN_MODE_TEXTUAL renders to an abstract representation, leaving it
up to device-specific software how to present this representation given the
capabilities, limitations, and conventions of the deivce.
We offer the following normative guidance:
The presentation should be as legible as possible to the user, given the capabilities of the device. If legibility could be sacrificed for other properties, we would recommend just using some other signing mode. Legibility should focus on the common case - it is okay for unusual cases to be less legible.
The presentation should be invertible if possible without substantial sacrifice of legibility. Any change to the rendered data should result in a visible change to the presentation. This extends the integrity of the signing to user-visible presentation.
The presentation should follow normal conventions of the device, without sacrificing legibility or invertibility.
As an illustration of these principles, here is an example algorithm for presentation on a device which can display a single 80-character line of printable ASCII characters:
The presentation is broken into lines, and each line is presented in sequence, with user controls for going forward or backward a line.
Expert mode screens are only presented if the device is in expert mode.
Each line of the screen starts with a number of
>characters equal to the screen's indentation level, followed by a
+character if this isn't the first line of the screen, followed by a space if either a
+has been emitted, or if this header is followed by a
+, or space.
If the line ends with whitespace or an
@character, an additional
@character is appended to the line.
The following ASCII control characters or backslash (
\) are converted to a backslash followed by a letter code, in the manner of string literals in many languages:
* a: U+0007 alert or bell
* b: U+0008 backspace
* f: U+000C form feed
* n: U+000A line feed
* r: U+000D carriage return
* t: U+0009 horizontal tab
* v: U+000B vertical tab
* `\`: U+005C backslash
All other ASCII control characters, plus non-ASCII Unicode code points, are shown as either:
* `\u` followed by 4 uppercase hex chacters for code points
in the basic multilingual plane (BMP).
* `\U` followed by 8 uppercase hex characters for other code points.
The screen will be broken into multiple lines to fit the 80-character limit, considering the above transformations in a way that attempts to minimize the number of lines generated. Expanded control or Unicode characters are never split across lines.
An introductory line.
key2: a string that ends in whitespace @
key3: a string that ends in a single ampersand - @@
>tricky key4<: note the leading space in the presentation
introducing an aggregate
> key5: false
> key6: a very long line of text, please co\u00F6perate and break into
>+ multiple lines.
> Can we do further nesting?
>> You bet we can!
The inverse mapping gives us the only input which could have generated this output (JSON notation for string data):
0 "An introductory line."
0 "key1: 123456"
0 "key2: a string that ends in whitespace "
0 "key3: a string that ends in a single ampersand - @"
0 ">tricky key4<: note the leading space in the presentation"
0 "introducing an aggregate"
1 "key5: false"
1 "key6: a very long line of text, please coöperate and break into multiple lines."
1 "Can we do further nesting?"
2 "You bet we can!"