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Concise Text Encoding

Version

Version 0 (prerelease)

This Document

This document describes the Concise Text Encoding (CTE) format, and how codecs for this format must behave.

Contents

Terms and Conventions

The following bolded, capitalized terms have specific meanings in this document:

Term Meaning
MUST (NOT) If this directive is not adhered to, the document or implementation is invalid.
SHOULD (NOT) Every effort should be made to follow this directive, but the document/implementation is still valid if not followed.
MAY (NOT) It is up to the implementation to decide whether to do something or not.
CAN Refers to a possibility which MUST be accommodated by the implementation.
CANNOT Refers to a situation which MUST NOT be allowed by the implementation.
OPTIONAL(LY) The implementation MUST support both the existence and the absence of the specified item.
OPTION(S) Configuration option(s) that implementations MUST provide.

Data descriptions and samples will generally be represented as follows:

  • Character sequences are enclosed within backticks: this is a character sequence
  • Byte sequences are represented as a series of two-digit hex values, enclosed within backticks and square brackets: [f1 33 91]
  • Data placeholders are put (between parentheses)
  • Some explanations will include excerpts from cte.dogma (in Dogma notation).

What is Concise Text Encoding?

Concise Text Encoding (CTE) is the text variant of Concise Encoding: a general purpose, human and machine friendly, compact representation of semi-structured hierarchical data.

The text format aims to present data in a human friendly way, encoding data in a manner that can be easily and unambiguously edited in a UTF-8 capable text editor while maintaining 1:1 compatibility with the binary format (which aims for compactness and machine processing efficiency).

Text Format

A CTE document is a UTF-8 encoded text document containing data arranged in an ad-hoc hierarchical fashion.

All text in a CTE document MUST be CTE safe. Validation for CTE safety MUST occur before all other processing or parsing (such as line ending conversion or escape-sequence decoding).

Examples:

  • CTE v1 empty document: c1 null
  • CTE v1 document containing the top-level integer value 1000: c1 1000
  • CTE v1 document containing a top-level list: c1 ["a" "b" "c"]
  • CTE v1 document containing a top-level map: c1 {"a"=1 "b"=2 "c"=3}

Character Safety

Because CTE documents must be editable by a human without losing information, there are certain codepoints that MUST NOT be present in a CTE document. These restrictions can be worked around in some contexts by encoding them as escape sequences.

All unassigned, reserved, surrogate, and invalid Unicode codepoints MUST NOT be present in a Concise Encoding document at all (even in escaped form).

The following characters MUST NOT be present in a CTE document (but may be escaped):

  • Unicode categories Cc (except tab, carriage return and linefeed), Co, Zl, Zp
  • Characters that look confusingly similar to CTE string delimiter characters.

For example, the CTE string representation "A” string" would be invalid due to the confusing "closing double-quote" character (), but it could be escaped like so: "A\[201d] string"

Here is (as of 2023) a complete list of lookalike Unicode characters. This list may change as the Unicode character set evolves over time. Codec developers MUST keep their implementation up to date with the latest lookalike characters.

Character Lookalikes (codepoints)
" 02ba, 02dd, 02ee, 02f6, 05f2, 05f4, 1cd3, 201c, 201d, 201f, 2033, 2034, 2036, 2037, 2057, 3003, ff02
\ 2216, 27cd, 29f5, 29f9, 2f02, 3035, 31d4, 4e36, fe68, ff3c, 1d20f, 1d23b

Text Safety Warning

Despite the above character safety requirements and other mitigations inherent in the CTE format, the complexity of Unicode makes it impossible for a text format to be as safe as a binary format.

CBE documents SHOULD always be preferred to CTE documents, except in cases where a human will be reading or writing the data.

Avoid ingesting CTE documents from untrusted sources (or at the very least, round-trip them to CBE and back to CTE and verify what comes out). There will always be ways to craft text documents that look legitimate to the human eye but actually contain something else.

Whitespace

Structural whitespace (carriage return, linefeed, space, and tab) is used to separate structural elements in a document (such as container contents). Extraneous structural whitespace is ignored.

Line Endings

The canonical line ending for CTE documents is LF (u+000a).

  • CTE decoders MUST accept LF and CRLF as line endings.
  • CTE encoders MUST output LF only as line endings.
LINE_END = CR? & LF;
LF       = '\[a]';
CR       = '\[d]';

Human Editability

In the spirit of human editability:

  • Implementations SHOULD avoid outputting unescaped characters that different editors tend to display inconsistently (for example, TAB).
  • Line lengths SHOULD be kept within reasonable amounts (80-120 columns) in order to avoid excessive horizontal scrolling in an editor.

Document Structure

A CTE document is composed of the following parts:

  1. A version header
  2. A series of optional intangible objects (which can include record types)
  3. A top-level data object
document = version_header
         & items(record_type, WSLC)
         & (data_object ! local_reference)
         ;

Example: A complete (and empty) CTE version 1 document:

c1
null

Version Header

The version header is composed of:

  1. The character 'c' (u+0063) or the character 'C' (u+0043)
  2. The numeric version number
  3. Mandatory whitespace
version_header = ('c' | 'C') & digit_dec+ & WSL;

Note: A decoder must accept lowercase 'c' (u+0063) or uppercase 'C' (u+0043), but an encoder MUST produce only lowercase 'c' (u+0063).

Example:

  • Version header (CTE version 1): c1

Numeric Types

Boolean

Represented by the text sequences true and false.

boolean = "true" | "false";

Integer

Integer values CAN be positive or negative, and CAN be represented in various bases. Negative values MUST be prefixed with a dash - as a sign character. Encoders MUST write values in lower case.

Integers CAN be specified in base 2, 8, 10, or 16. Bases other than 10 require a prefix:

Base Name Digits Prefix Example Decimal Equivalent
2 Binary 01 0b -0b1100 -12
8 Octal 01234567 0o 0o755 493
10 Decimal 0123456789 900000 900000
16 Hexadecimal 0123456789abcdef 0x 0xdeadbeef 3735928559 
integer      = neg? & uinteger;
integer_bin  = neg? & uinteger_bin;
integer_oct  = neg? & uinteger_oct;
integer_dec  = neg? & uinteger_dec;
integer_hex  = neg? & uinteger_hex;

uinteger     = uinteger_bin | uinteger_oct | uinteger_dec | uinteger_hex;
uinteger_bin = prefix_bin & digits_bin;
uinteger_oct = prefix_oct & digits_oct;
uinteger_dec = digits_dec;
uinteger_hex = prefix_hex & digits_hex;

digits_bin   = digit_bin & ('_'? & digit_bin)*;
digits_oct   = digit_oct & ('_'? & digit_oct)*;
digits_dec   = digit_dec & ('_'? & digit_dec)*;
digits_hex   = digit_hex & ('_'? & digit_hex)*;
digit_bin    = '0'~'1';
digit_oct    = '0'~'7';
digit_dec    = '0'~'9';
digit_hex    = '0'~'9' | 'a'~'f' | 'A'~'F';
neg          = '-';
prefix_bin   = '0' ('b' | 'B');
prefix_oct   = '0' ('o' | 'O');
prefix_hex   = '0' ('x' | 'X');

Encoders MUST output integers in base 10 by default, and MAY offer configuration to output different bases.

Floating Point

A floating point number is conceptually composed of an implied radix (signified by an OPTIONAL prefix), a significand portion (composed of a whole part and an OPTIONAL fractional part), and an OPTIONAL exponential portion, such that the value is calculated as:

value = whole.fractional × radixᵉˣᵖᵒⁿᵉⁿᵗ

Where radix is 10 for base-10 notation, and 2 for base-16 notation.

Encoders MUST output decimal float values in base-10 notation and binary float values in base-16 notation by default, and MAY offer configuration to output different bases.

Base-10 Notation

Base-10 notation is used to represent decimal floating point numbers.

The exponential portion of a base-10 number is denoted by the character e, followed by the signed size of the exponent (using OPTIONAL + for positive, and mandatory - for negative). The exponential portion is a signed base-10 number representing the power-of-10 to multiply the significand by. Values SHOULD be normalized (only one digit to the left of the decimal point) when using exponential notation.

value = significand × 10ᵉˣᵖᵒⁿᵉⁿᵗ

Although there is technically no maximum number of significant digits or exponent digits for base-10 floating point notation, care should be taken to ensure that the receiving end will be able to store the value. For example, if the receiving end only supports the 64-bit ieee754 floating point type, then it can only represent values with up to 16 significant digits and an exponent range roughly from 10⁻³⁰⁷ to 10³⁰⁷.

float_dec     = (neg? & digits_dec & (('.' & digits_dec & exponent_dec?) | exponent_dec)) | float_special;
float_special = (neg? & "inf") | "nan" | "snan";
exponent_dec  = ('e' | 'E') & neg? & digits_dec;

Examples:

c1
[
    -3.14
    6.411e+9 // 6411000000
    6.411e9  // 6411000000
    6411e6   // 6411000000
    6.411e-9 // 0.000000006411
]

Base-16 Notation

Base-16 notation is used to represent binary floating point numbers because it allows 100% accurate representation of the actual value.

Base-16 notation MUST have a prefix of 0x, and the exponential portion is denoted by the character p. The exponential portion is a signed base-10 number representing the power-of-2 to multiply the significand by. The exponent's sign character CAN be omitted if it's positive. Values SHOULD be normalized.

value = significand × 2ᵉˣᵖᵒⁿᵉⁿᵗ

float_hex     = (neg? & prefix_hex & digits_hex & (('.' & digits_hex & exponent_hex?) | exponent_hex)) | float_special;
float_special = (neg? & "inf") | "nan" | "snan";
exponent_hex  = ('p' | 'P') & neg? & digits_dec; # hex float exponent is in decimal, not hex.

To maintain compatibility with CBE, values in base-16 notation MUST NOT exceed the range of ieee754 64-bit binary float. A value outside of this range is an error condition.

Examples:

c1
[
    0xa.3fb8p+42 // a.3fb8 x 2⁴²
    -0x1p0       // -1
]

Special Floating Point Values

c1
[
    inf  // Infinity
    -inf // Negative Infinity
    nan  // Not a Number (quiet)
    snan // Not a Number (signaling)
]

Floating Point Rules

  • Encoders MUST output exponent portion markers in lowercase only (e or p).
  • Decoders MUST accept uppercase (E or P) and lowercase (e or p) exponent portion markers.
  • There MUST be at least one digit on each side of a radix point (.) when present.
Invalid Valid Notes
-1. -1.0 Or just use the integer value -1
.1 0.1
.218901e+2 21.8901 Or 2.18901e+1, or 0.218901e+2

Numeric Whitespace

The _ character CAN be used as "numeric whitespace" when encoding integers and floating point numbers. Other whitespace characters are not allowed.

CTE encoders MAY offer configuration options to output numeric whitespace, but MUST by default output no numeric whitespace.

Rules:

  • Only integer and floating point types CAN contain numeric whitespace.
  • Special floating point values MUST NOT contain numeric whitespace.
  • Numeric whitespace CAN only occur between two adjacent numeric digits (0-9, a-f, depending on numeric base).
  • Numeric whitespace characters MUST be ignored when decoding numeric values.
digits_bin = digit_bin & ('_'? & digit_bin)*;
digits_oct = digit_oct & ('_'? & digit_oct)*;
digits_dec = digit_dec & ('_'? & digit_dec)*;
digits_hex = digit_hex & ('_'? & digit_hex)*;
digit_bin  = '0'~'1';
digit_oct  = '0'~'7';
digit_dec  = '0'~'9';
digit_hex  = '0'~'9' | 'a'~'f' | 'A'~'F';

Examples:

Valid:

c1
[
    1_000_000        // 1000000
    4_3.5_5_4e9_0    // 43.554e90
    -0xa.fee_31p1_00 // -0xa.fee31p100
]

Invalid:

  • _1000000
  • 1000000_
  • 43_.554e90
  • 43,_554e90
  • 43.554_e90
  • -_43.554e90
  • -_0xa.fee31p100
  • -0xa.fee31p_100
  • -0_xa.fee31p100

UID

An rfc4122 UUID string representation.

uid       = digit_hex{8} & '-' & digit_hex{4} & '-' & digit_hex{4} & '-' & digit_hex{4} & '-' & digit_hex{12};
digit_hex = '0'~'9' | 'a'~'f' | 'A'~'F';

Example:

c1
123e4567-e89b-12d3-a456-426655440000

Temporal Types

Temporal types record time with varying degrees of precision.

Fields other than year CAN be pre-padded with zeros (0) up to their maximum allowed digits.

Date

A date is made up of the following fields, separated by a dash character (-):

Field Mandatory Min Value Max Value Min Digits Max Digits
Year Y -∞ 1
Month Y 1 12 1 2
Day Y 1 31 1 2
  • BC years are prefixed with a dash (-).
date      = neg? & digit_dec+ & '-' & digit_dec{1~2} & '-' & digit_dec{1~2};
digit_dec = '0'~'9';
neg       = '-';

Examples:

c1
[
    2019-8-5   // August 5, 2019
    5081-03-30 // March 30, 5081
    -300-12-21 // December 21, 300 BC (proleptic Gregorian)
]

Time

A time is made up of the following mandatory and OPTIONAL fields:

Field Mandatory Separator Min Value Max Value Min Digits Max Digits
Hour Y 0 23 1 2
Minute Y : 0 59 2 2
Second Y : 0 60 2 2
Subseconds N . 0 999999999 0 9
Time Zone N / - - - - 
time = digit_dec{1~2} & ':' & digit_dec{2} & ':' & digit_dec{2} & ('.' & digit_dec{1~9})? & time_zone?;

Examples:

c1
[
    09:04:21                // 9:04:21 UTC
    23:59:59.999999999      // 23:59:59 and 999999999 nanoseconds UTC
    12:05:50.102/Z          // 12:05:50 and 102 milliseconds UTC
    4:00:00/Asia/Tokyo      // 4:00:00 Tokyo time
    17:41:03/-13.54/-172.36 // 17:41:03 Samoa time
    9:00:00/L               // 9:00:00 local time
]

Timestamp

A timestamp combines a date and a time, separated by a slash character (/).

timestamp = date & '/' & time;

Examples:

c1
[
    2019-01-23/14:08:51.941245            // January 23, 2019, at 14:08:51 and 941245 microseconds, UTC
    1985-10-26/01:20:01.105/M/Los_Angeles // October 26, 1985, at 1:20:01 and 105 milliseconds, Los Angeles time
    5192-11-01/03:00:00/48.86/2.36        // November 1st, 5192, at 3:00:00, at whatever is in the place of Paris at that time
]

Time Zones

The time zone is an OPTIONAL field. If omitted, it is assumed to be Zero (UTC).

time_zone = tz_area_location | tz_coordinates | utc_offset;

Area/Location

An area/location time zone is generally written in the form Area/Location, but there exist shorthands and legacy time zones that do not have a separator.

tz_area_location = '/' & (tz_a_l_component & ('/' & tz_a_l_component)* | tz_a_l_legacy);
tz_a_l_component = ('a'~'z' | 'A'~'Z' | '.' | '-' | '_' )+;
tz_a_l_legacy    = ('A'~'Z') & ('a'~'z' | 'A'~'Z' | '0'~'9' | '-' | '+' | '_' | '/')+;

Examples:

  • /E/Paris
  • /Asia/Tokyo
  • /America/Indiana/Petersburg (which has area America and location Indiana/Petersburg)
  • /Etc/UTC == Zero == Z
  • /L

Global Coordinates

Global coordinates are written as latitude and longitude in degrees to a precision of hundredths, separated by a slash character (/).

  • Negative values MUST be prefixed with a dash character (-)
  • A period (.) is used as a fractional separator.
tz_coordinates = '/' & tz_coordinate & '/' & tz_coordinate;
tz_coordinate  = neg? & digit_dec+ & ('.' & digit_dec+)?;

Examples:

  • /50.45/30.52 (Kyiv, near Independence Square)
  • /-13.53/-172.37 (Samoa)

UTC

Simply omit the time zone entirely, which causes the time zone to default to UTC.

UTC Offset

UTC offsets are recorded by using a + (for positive offsets) or - (for negative offsets) character as the time zone separator instead of the / character, with the hours and minutes given in the form hhmm.

utc_offset = ('+' | '-') & digit_dec{4};

Examples (using timestamps):

c1
[
    1985-10-26/01:20:01.105+0700
    2000-01-14/10:22:00-0200
]

Why not ISO 8601 or RFC 3339?

RFC 3339 was developed as a greatly simplified (and also open) profile of ISO 8601 to be used in internet protocols. RFC 3339's criticisms of ISO 8601 are valid:

  • It has bad defaults.
  • It tries to do too many things.
  • It has too much optional functionality (most of which is unused in the real world).
  • It's non-free, making it even harder to write compliant, bug-free implementations (or trust any that claim to be).

This renders ISO 8601 overcomplicated and prone to misinterpretation, incompatibilities, and bugs.

RFC 3339 is a much simpler design for timestamped internet events, and is well suited to that purpose. However, it lacks functionality that a general purpose date format would require:

  • Like ISO 8601, it only supports time offsets (+01:00, -13:00, etc), not real time zones (link: why this is important).
  • It doesn't support BCE dates.
  • It allows multiple interpretations of year values less than 4 digits long, which is a security risk and a source of bugs.

String Types

String types MUST contain only valid UTF-8 characters. The contents are enclosed within double-quote (") delimiters. All characters leading up to the closing double-quote (including whitespace) are considered part of the string sequence. String types CAN contain escape sequences.

CTE unsafe characters MUST always be escaped.

Double-quotes (") and backslash (\) (as well as their lookalikes) MUST be encoded as escape sequences (except when inside of a verbatim sequence). CR (u+000d) MUST be escaped. TAB (u+0009) and LF (u+000a) SHOULD be escaped as well to ensure that a text editor doesn't alter them.

string_type           = '"' & (char_string | escape_sequence)* & '"';
char_string           = char_cte ! ('"' | '\\' | delimiter_lookalikes);
char_cte              = unicode(Cf,L,M,N,P,S,Zs) | WSL;
delimiter_lookalikes  = '\[02ba]' | '\[02dd]' | '\[02ee]' | '\[02f6]' | '\[05f2]' | '\[05f4]'
                      | '\[1cd3]' | '\[201c]' | '\[201d]' | '\[201f]' | '\[2033]' | '\[2034]'
                      | '\[2036]' | '\[2037]' | '\[2057]' | '\[20f2]' | '\[2216]' | '\[27cd]'
                      | '\[29f5]' | '\[29f9]' | '\[3003]' | '\[3035]' | '\[31d4]' | '\[4e36]'
                      | '\[fe68]' | '\[ff02]' | '\[ff3c]' | '\[1d20f]' | '\[1d23b]'
                      ;
WSL                   = WS | LINE_END;
WS                    = HT | SP;
LINE_END              = CR? & LF;
HT                    = '\[9]';
LF                    = '\[a]';
CR                    = '\[d]';
SP                    = '\[20]';

Example:

"a string"

String Type Validation

CTE decoders MUST validate string types in the following order (or effectively equivalent):

  1. Validate the raw string contents for CTE safety.
  2. Decode all escape sequences to produce a final string.
  3. Validate the final string for UTF-8 validity and apply NUL stuffing if necessary.

Escape Sequences

Within string types, escape sequences CAN be used to encode data that would otherwise be cumbersome or impossible to represent in CTE. Backslash (\) acts as an escape sequence initiator, followed by an escape type character and possible payload data depending on the type:

Escape Type Character Interpretation
u+0074 (t) horizontal tab (u+0009)
u+006e (n) linefeed (u+000a)
u+0072 (r) carriage return (u+000d)
u+0022 (") double quote (u+0022)
u+002a (*) asterisk (u+002a)
u+002f (/) slash (u+002f)
u+005c (\) backslash (u+005c)
u+005f (_) non-breaking space (u+00a0)
u+002d (-) soft hyphen (u+00ad)
u+000a (linefeed) continuation
u+002b ([) Unicode codepoint
u+002e (.) verbatim sequence

Any escape type character not in the above list is invalid.

escape_sequence       = '\\' & ('t' | 'n' | 'r' | '"' | '*' | '/' | '\\' | '_' | '-'
                      | escape_continuation | escape_codepoint | escape_verbatim)
                      ;

Continuation

A continuation escape sequence causes the decoder to ignore all structural whitespace characters until it encounters a character that is not structural whitespace. The escape character (\) followed by LF (u+000a) or CRLF (u+000d u+000a) initiates a continuation.

escape_continuation = '\\' & LINE_END & WS*;

Example:

c1 "The only people for me are the mad ones, the ones who are mad to live, mad to talk, \
     mad to be saved, desirous of everything at the same time, the ones who never yawn or \
     say a commonplace thing, but burn, burn, burn like fabulous yellow roman candles \
     exploding like spiders across the stars."

The above string is interpreted as:

The only people for me are the mad ones, the ones who are mad to live, mad to talk, mad to be saved, desirous of everything at the same time, the ones who never yawn or say a commonplace thing, but burn, burn, burn like fabulous yellow roman candles exploding like spiders across the stars.

Unicode Codepoint

A Unicode codepoint escape sequence represents a single Unicode character as a hexadecimal codepoint.

The escape sequence begins with a backslash (\) character, followed by an opening square brace ([), followed by hexadecimal digits representing the codepoint, and is finally terminated by a closing square brace (]). OPTIONAL leading zeroes are allowed for stylistic purposes (e.g. \[0020]), but encoders MUST by default not output leading zeroes.

escape_codepoint = '\\[' & digit_hex+ & ']';

Warning: Decoders MUST NOT allow codepoints to overflow (e.g. \[10000000000000020] overflowing a uint32 or uint64 accumulator to produce codepoint 0x20). An out-of-range codepoint is an error condition.

Examples:

Sequence Digits Codepoint Character
\[c] 1 u+000c Form Feed
\[df] 2 u+00df ß (Eszett)
\[101] 3 u+0101 ā (a macron)
\[2191] 4 u+2191 ↑ (up arrow)
\[1f415] 5 u+1f415 🐕 (dog)

"gro\[df]e" = "große"

Verbatim Sequence

A verbatim escape sequence works like a "here document". It's composed as follows:

  • Verbatim sequence escape initiator (\.).
  • An end-of-sequence sentinel, which is a sequence of characters with the Unicode categories (L, M, N, P, S).
  • An unescaped whitespace terminator (either SPACE u+0020 LF u+000a, or CRLF u+000d u+000a) to terminate the end-of-sequence sentinel.
  • The string contents.
  • A second instance of the end-of-sequence sentinel (without whitespace terminator). Note: Unlike in many languages, this sequence does not have to occur alone on its own line.
escape_verbatim = '.' & var(terminator, char_sentinel+) & (LINE_END | SP) & char_cte* & terminator;
char_sentinel   = unicode(L,M,N,P,S);
char_cte        = unicode(Cf,L,M,N,P,S,Zs) | WSL;

Notes:

  • Verbatim sequence sentinels are case sensitive.
  • TAB (u+0009) MUST NOT be used as an end-of-sequence sentinel terminator because any editor that converts tabs to spaces would effectively alter the verbatim contents (only the first space would terminate the sentinel; the other spaces would become part of the verbatim data).
  • A malformed sentinel terminator is an error condition.

Example:

c1
"Verbatim sequences can occur anywhere escapes are allowed.\n\.@@@
In verbatim sequences, everything is interpreted literally until the
end-of-string sentinel is encountered (in this case three @ characters).

Characters like " and \ are no longer special: \n and \t appear as-is.

Continuations are also not processed in a verbatim sequence. \
          For example, this line really is indented 10 spaces.

Normal processing resumes after the terminator@@@, so escape \
          sequences\nare once again interpreted."

Which decodes to:

Verbatim sequences can occur anywhere escapes are allowed.
In verbatim sequences, everything is interpreted literally until the
end-of-string sentinel is encountered (in this case three @ characters).

Characters like " and \ are no longer special: \n and \t appear as-is.

Continuations are also not processed in a verbatim sequence. \
          For example, this line really is indented 10 spaces.

Normal processing resumes after the terminator, so escape sequences
are once again interpreted.

String

A string is the most basic string type, enclosed within double-quote delimiters (").

string              = stringlike(char_cte);
stringlike(allowed) = '"' & ((allowed ! ('"' | '\\' | delimiter_lookalikes)) | escape_sequence)* & '"';
char_cte            = unicode(Cf,L,M,N,P,S,Zs) | WSL;

Example:

c1
"Line 1\nLine 2\nLine 3"

Which is a document containing the string:

Line 1
Line 2
Line 3

Resource Identifier

A resource identifier is encoded as a string type restricted to rfc3987, enclosed within double-quote delimiters (") and prefixed with an at symbol (@).

resource_id = '@' & stringlike(char_rid);
char_rid    = """https://www.rfc-editor.org/rfc/rfc3987""";

Note: A decoder MUST only interpret CTE escape sequences, not resource-specific escape sequences (such as percent encoding). Resource-specific escape sequences MUST be passed unmodified to the application layer.

Example:

c1
[
    // CTE decodes this as `http://x.y.z?quote="`
    // The application layer interprets it as `http://x.y.z?quote="`
    @"http://x.y.z?quote=\""

    // CTE decodes this as `http://x.y.z?quote=%22`
    // The application layer interprets it as `http://x.y.z?quote="`
    @"http://x.y.z?quote=%22"
]

Arrays

Array-like data can be represented in elemental or string form, depending on the type.

Elemental Form

An elemental form array begins with an @ character, followed by the array type, and finally the array elements between [ and ] characters.

array(type, elem_type) = '@' & type & '[' & items(elem_type, WSL) & ']';
items(type, separator) = separator* & (type & (separator+ & type)* & separator*)?;

Example:

c1
@i32[1 -1000 10000 -100000 1000000]

String Form

The string form is available as an alternative representation in some cases (media and custom types). It begins with an @ character, followed by the array type, followed by a string enclosed by double-quotes (").

array_stringform(type) = '@' & type & stringlike;
stringlike             = '"' & ((char_cte ! ('"' | '\\' | delimiter_lookalikes)) | escape_sequence)* & '"';

Example:

c1
[
    // Custom type as a string
    @1"2.94+3i"

    // Media as a string
    @application/x-sh"#!/bin/sh\
                      echo hello world\
                     "
]

Array Types

The following array types are available:

Array Type Element Base Description Encoding Kind
b 2 Bit Element
u8 2, 8, 10, 16 8-bit unsigned integer Element
u16 2, 8, 10, 16 16-bit unsigned integer Element
u32 2, 8, 10, 16 32-bit unsigned integer Element
u64 2, 8, 10, 16 64-bit unsigned integer Element
i8 2, 8, 10, 16 8-bit signed integer Element
i16 2, 8, 10, 16 16-bit signed integer Element
i32 2, 8, 10, 16 32-bit signed integer Element
i64 2, 8, 10, 16 64-bit signed integer Element
f16 10, 16 16-bit binary float (bfloat) Element
f32 10, 16 32-bit binary float (ieee754) Element
f64 10, 16 64-bit binary float (ieee754) Element
uid 16 128-bit UID Element
<type-code> 16 Custom Types Element or string
<media-type> 16 Media Element or string

Array type designators are case-insensitive.

An invalid array type field is an error condition.

For array types that support multiple bases, elements MAY be represented in different bases by applying a base prefix (0b for base 2, 0o for base 8, 0x for base 16) to an element (provided the element type supports it).

CTE encoders MUST default to base-10 notation for integer array elements, and MUST default to base-16 notation for floating point array elements, and MAY offer configuration to output different bases.

Array Type Suffix

OPTIONALLY, if an array type supports multiple element bases, a suffix CAN be appended to a numeric array type specifier to indicate the implied base of all elements in that array (provided the array element type supports such a base). When an implied base is specified, all elements MUST be interpreted in that base, and MUST NOT themselves have a base prefix.

Array Type Suffix Base Example
b 2 @u8b[10011010 00010101]
o 8 @i16o[-7445 644]
x 16 @f32x[a.c9fp20 -1.ffe9p-40]

CTE encoders MUST NOT produce array type suffixes by default, but MAY be configured to do so.

Examples:

c1
[
    @u8x[9f 47 cb 9a 3c]
    @f32[1.5 0x4.f391p100 30 9.31e-30]
    @i16[0b1001010 0o744 1000 0x7fff]
    @uid[3a04f62f-cea5-4d2a-8598-bc156b99ea3b 1d4e205c-5ea3-46ea-92a3-98d9d3e6332f]
    @b[11010]
]

Bit Array Elements

Bit array elements are represented using 0 for false and 1 for true. Whitespace between elements is OPTIONAL when encoding a bit array.

array_bit = '@b[' & items(digit_bin, WSL?) & ']';
digit_bin = '0'~'1';

Examples:

c1
[
    @b[1 0 0 1] // bits 1, 0, 0, 1
    @b[1001]    // bits 1, 0, 0, 1
    @b[10 01]   // bits 1, 0, 0, 1
]

Float Array Elements

Like their standalone counterparts, special float values are allowed in floating point arrays:

@f32[0x1.5da nan -inf 0xc.1f3p38]

Float array element values written in decimal form will be silently rounded as they're converted to binary floats. This is unavoidable due to differences in float parsers on different platforms, and is another reason why you should prefer CBE over CTE when ingesting data from an untrusted source (see security and limits).

Media

In media objects, the array type field is the media type, and the contents contains the media data:

media                  = array_stringform(media_type) | array(media_type, hex_byte);
media_type             = media_type_major & '/' & media_type_minor;
media_type_major       = char_media_first & char_media_next*;
media_type_minor       = char_media_next+;

Examples:

c1
[
    @text/plain"stuff"          // text encoded media
    @text/plain[73 74 75 66 66] // byte encoded media
    @text/plain[]               // empty media
    @text/plain""               // empty media
]

Media Contents

If the actual media contents consists only of valid UTF-8 text, it CAN be represented in string form. Otherwise, it MUST be represented in binary form using hex byte values as if it were a u8x array:

  • As text: @type/subtype"contents"
  • As binary: @type/subtype[63 6f 6e 74 65 6e 74 73]

Example:

c1
@application/x-sh[23 21 2f 62 69 6e 2f 73 68 0a 0a 65 63 68 6f 20 68 65 6c 6c 6f 20 77 6f 72 6c 64 0a]

Which is equivalent to:

c1
@application/x-sh"#!/bin/sh

echo hello world
"

Both of the above examples represent a document containing the shell script:

#!/bin/sh

echo hello world

Custom Types

In custom objects, the type field is the text representation of the unsigned integer custom type. Custom types can be encoded using a hex-byte binary form and a string-based textual form.

custom_type      = array_stringform(custom_type_code) | array(custom_type_code, hex_byte);
custom_type_code = digit_dec+;

The binary form is encoded like a u8x array (hex encoded byte elements).

Example: Binary encoded custom type value with type code 99:

c1
@99[01 f6 28 3c 40 00 00 40 40]

The textual form is encoded using a quoted string.

Example: Text encoded custom type value with type code 99:

c1
@99"2.94+3i"

Container Types

List

A list begins with an opening square bracket [, contains structural whitespace separated contents, and finishes with a closing square bracket ].

list                   = '[' & items(data_object, WSLC) & ']';
items(type, separator) = separator* & (type & (separator+ & type)* & separator*)?;

Example:

c1
[
    1
    "two"
    3.1
    {}
]

Map

A map begins with an opening curly brace {, contains structural whitespace separated key-value pairs, and finishes with a closing curly brace }.

Map entries are split into key-value pairs using the equals = character and OPTIONAL structural whitespace. Key-value pairs MUST be separated from each other using structural whitespace. A key without a paired value is an error condition.

map       = '{' & items(key_value, WSLC) & '}';
key_value = keyable_object & WSLC* & '=' & WSLC* & data_object;

Example:

c1
{
    1 = "alpha"
    2 = "beta"
    "a map" = {"one"=1 "two"=2}
}

Record

A record begins with @, followed by the identifier of a record type that MUST have been defined at the top of the document, followed by {, followed by a series of whitespace separated values in the same order that their keys are defined in the associated record type, and is terminated with }.

record = '@' & identifier & '{' & items(data_object, WSLC) & '}';

Example:

c1
@vehicle<"make" "model" "drive" "sunroof">
[
    @vehicle{"Ford"       "Explorer"   "4wd" true }
    @vehicle{"Toyota"     "Corolla"    "fwd" false}
    @vehicle{"Honda"      "Civic"      "fwd" false}
    @vehicle{"Alfa Romeo" "Giulia 952" "awd" true }
]

Node

A node begins with an opening parenthesis (, contains a value (object) followed by zero or more whitespace separated child nodes, and is closed with a closing parenthesis ).

node = '(' & WSLC* & data_object & items(data_object, WSLC) & ')';

Nodes are recorded in depth-first, node-right-left order, which ensures that the textual representation looks like the actual tree structure it describes when rotated 90 degrees clockwise.

Example:

c1
// The tree structure:
//        2
//       / \
//      5   7
//     /   /|\
//    9   6 1 2
//   /   / \
//  4   8   5
//
(2
    (7
        2
        1
        (6
            5
            8
        )
    )
    (5
        (9
            4
        )
    )
)

Viewed rotated, it resembles the tree it describes:

tree rotated

Edge

An edge container is composed of the delimiters @( and ), containing the whitespace separated source, description, and destination.

edge = '@(' & WSLC* & non_null_object & WSLC+ & data_object & WSLC+ & non_null_object & WSLC* & ')';

Edges are most commonly used in conjunction with references or resource identifiers to produce arbitrary graphs.

Examples:

Weighted graph edge:

c1
{
    "vertices" = [
      &a:{}
      &b:{}
    ]
    "edges" = [
      @($a 200 $b)
    ]
}

Relationship graph edge:

c1
@(
    @"https://springfield.gov/people#homer_simpson"
    @"https://example.org/wife"
    @"https://springfield.gov/people#marge_simpson"
)

Other Types

Null

Null is encoded as null.

null = "null";

Pseudo-Objects

Local Reference

A local reference begins with a reference initiator ($), followed immediately (with no whitespace) by the identifier of a marker that has been defined elsewhere in the current document.

local_reference = '$' & identifier;

Example:

c1
{
    "some_object" = {
        "my_string" = &remember_me:"Remember this string"
        "my_map" = &1:{
            "a" = 1
        }
    }

    "reference_to_string" = $remember_me
    "reference_to_map" = $1
}

Remote Reference

A remote reference is encoded as a string type, enclosed within double-quote delimiters (") and prefixed with a reference initiator ($).

remote_reference    = '$' & stringlike(char_rid);
stringlike(allowed) = '"' & ((allowed ! ('"' | '\\' | delimiter_lookalikes)) | escape_sequence)* & '"';
char_rid            = """https://www.rfc-editor.org/rfc/rfc3987""";

Example:

c1
{
    "reference_to_local_doc" = $"common.cte"
    "reference_to_remote_doc" = $"https://somewhere.com/my_document.cbe?format=long"
    "reference_to_local_doc_marker" = $"common.cte#legalese"
    "reference_to_remote_doc_marker" = $"https://somewhere.com/my_document.cbe?format=long#examples"
}

Invisible Objects

Comment

Comments CAN be written in single-line or multi-line form, and do not process escape sequences.

Comments MUST ONLY contain CTE safe characters.

Single Line Comment

A single line comment begins at the sequence // and continues until the next LF (u+000a) is encountered. No checks for nested comments are performed.

comment_single_line = "//" & (char_cte* ! LINE_END) & LINE_END;

Multiline Comment

A multiline comment (aka block comment) begins at the sequence /* and is terminated by the sequence */. Multiline comments support nesting, meaning that further /* sequences inside the comment will start sub-comments that MUST also be terminated by their own */ sequence. No processing of the comment contents other than detecting comment begin and comment end is performed.

comment_multi_line = "/*" & ((char_cte* ! "/*") | comment_multi_line) & "*/";

Note: Commenting out strings containing /* or */ could potentially cause parse errors because the parser won't have any contextual information about the sequences, and will simply treat them as "comment begin" and "comment end". This edge case could be mitigated by preemptively escaping all occurrences of /* and */ in string types:

c1
{
    // Preemptively escape the "/" to avoid a false nested comment end
    "comment end" = "*\/"

    // Preemptively escape the "*" to avoid a false nested comment begin
    "comment begin" = "/\*"

/*
    // When block-commented out, it still parses properly
    "comment end" = "*\/"
    "comment begin" = "/\*"
*/
}

Example:

c1
// Comment before top level object
{
    // Comment before the "name" object.
    // And another comment.
    "name" = "Joe Average" // Comment after the "Joe Average" object.

    "email" = // Comment after the "email" key.
    /* Multiline comment with nested comment inside
      @"mailto:joe@average.org"
      /* Nested multiline
         comments are allowed */
    */
    @"mailto:someone@somewhere.com"

    "a" = "We're inside a string, so /* this is not a comment; it's part of the string! */"

    // Comment before the end of the top-level object (the map), but not after!
}

Padding

Padding is not supported in CTE. An encoder MUST skip all padding when converting CBE to CTE.

Structural Objects

Record Type

A record type begins with @, followed by an identifier, followed by <, followed by a series of whitespace separated keys, and is terminated with >.

record_type = '@' & identifier & '<' & items(keyable_object, WSLC) '>';

Example:

c1
// Define a record type:
@dog<"name" "gender">

// Now we can create records of this type:
[
    @dog{"Fido" "m"}
    @dog{"Fifi" "f"}
]

Marker

A marker begins with &, followed by a marker identifier, followed by :, followed by the marked data object.

marker = '&' & identifier & ':' & data_object;

Example:

c1
[
    &remember_me:"Remember this string"
    &1:{"a" = 1}
]

The string "Remember this string" is marked with the ID remember_me, and the map {"a"=1} is marked with the ID 1.

Empty Document

An empty document in CTE is signified by using null type as the top-level object:

c1
null

Letter Case

A CTE encoder MUST output entirely in lower case, except in the following situations:

  • String types CAN contain uppercase and lowercase characters.
  • Comments CAN contain uppercase and lowercase characters.
  • Identifiers CAN contain uppercase and lowercase characters.
  • Time zones are case sensitive, and usually contain uppercase and lowercase characters.

For the above situations, a CTE encoder MUST preserve letter case. In all other situations, a CTE encoder MUST convert to lower case.

Letter Case for Decoders

Humans will inevitably get letter case wrong when writing into a CTE document (because they copy-pasted it from somewhere, because they have caps-lock on, because it's just muscle memory to do it that way, etc). Rejecting a document on letter case grounds would be poor U/X, so some decoder lenience is necessary:

A CTE decoder MUST accept documents that break lowercase requirements (including version specifier, hexadecimal digits, array types, escape sequences, etc).

Example:

A CTE decoder MUST accept documents such as:

C1
[
    @U8[0XF1 0X5A]
    "Some text\Nwith a newline and a \[1F415]"
    0XFFFF
    0B10010101
    INF
    NAN
    1.8E+22
]

However, the following would be invalid:

  • 4:00:00/ASIA/TOKYO (time zones are case sensitive)
  • [ &a:"marked text" $A ] (identifiers are case sensitive)
  • "\.ZZZ terminated by zzz" (verbatim sentinels are case sensitive)

And the following would likely fail at the application layer (but not in the CTE decoder):

Structural Whitespace

Structural whitespace is a sequence of whitespace characters whose purpose is to separate objects in a CTE document (for example, separating objects in a list [1 2 3 4]). Such characters are not interpreted literally, are interchangeable, and can be repeated any number of times without altering the meaning or structure of the document.

WSL      = WS | LINE_END;
WS       = HT | SP;
LINE_END = CR? & LF;
HT       = '\[9]';
LF       = '\[a]';
CR       = '\[d]';
SP       = '\[20]';

Structural Whitespace CAN occur:

  • Around an object.
  • Around array and container delimiters ([, ], {, =, }, (, ), <, >)

Examples:

  • [ 1 2 3 ] is equivalent to [1 2 3]
  • @u8x[ 01 02 03 04 ] is equivalent to @u8x[01 02 03 04]
  • { 1="one" 2 = "two" 3= "three" 4 ="four"} is equivalent to {1="one" 2="two" 3="three" 4="four"}

Structural Whitespace MUST occur:

  • Between the version header and the first object.
  • Between the end-of-string sentinel and the beginning of the data in a verbatim sequence.
  • Between a primitive type array element type specifier and the array contents, and between array elements.
  • Between values in a list (["one""two"] is an error condition).
  • Between key-value pairs in a map ({1="one"2="two"} is an error condition).

Whitespace MUST NOT occur:

Pretty Printing

Pretty printing is the act of laying out structural whitespace in a CTE document such that it is easier for humans to parse. CTE documents SHOULD always be pretty-printed (except when intended for single-line log entries) because the purpose of CTE is to be read by humans.

Use CBE wherever possible instead of minified CTE, and convert to (pretty-printed) CTE only in places where a human will be reading the data.

The following sections describe how to pretty-print CTE documents.

Right Margin

The right margin (maximum column before breaking an object into multiple lines) SHOULD be kept "reasonable". "Reasonable" is difficult to define because it depends in part on the kind of data the document contains, and the container depth.

In general, 120 columns SHOULD always be considered reasonable, with larger margins depending on the kind and depth of data the document is likely to contain.

Indentation

The canonical indentation is 4 spaces ( ). CTE encoders SHOULD always emit indentation unless the destination is a single-line log entry.

Pretty Printing Lists

Objects in a list SHOULD be placed on separate lines.

c1
[
    @"https://www.imdb.com/title/tt0090605/"
    @"https://www.imdb.com/title/tt1029248/"
]

If a list is empty, the closing ] SHOULD be on the same line.

c1
[]

Short lists containing small objects MAY be placed entirely on one line.

c1
["a" "b" "c" "d"]

Pretty Printing Maps

There SHOULD be a space between keys, values and the = in key-value pairs, and each key-value pair SHOULD be on a separate line.

c1
{
    "aliens" = @"https://www.imdb.com/title/tt0090605/"
    "moribito" = @"https://www.imdb.com/title/tt1029248/"
}

If a map is empty, the closing } SHOULD be on the same line.

c1
{}

Small maps containing small objects MAY be placed entirely on one line. In such a case, omit the spaces around the =.

c1
{"a"="b" "c"="d"}

Pretty Printing Record Types

Record types SHOULD follow a similar pretty printing strategy to lists.

Pretty Printing Records

Records SHOULD follow a similar pretty printing strategy to lists.

Pretty Printing Nodes

In order to keep the tree as readable as possible to a human:

  • There SHOULD NOT be whitespace between the left ( and the node value.
  • All child nodes SHOULD be on separate lines at the next indentation depth.
  • If the node has child nodes, the closing ) SHOULD be on a separate line, at the same indentation depth as the (.
  • If the node has no children, the closing ) SHOULD be on the same line.

See the example in node.

Pretty Printing Edges

Edge components SHOULD be broken up into multiple lines if they're too long.

c1
@(
    @"https://springfield.gov/people#homer_simpson"
    @"https://example.org/wife"
    @"https://springfield.gov/people#marge_simpson"
)

Pretty Printing Strings

Strings SHOULD use continuations if the line is getting too long.

c1
[
    "All that most maddens and torments; all that stirs up the lees of things; \
    all truth with malice in it; all that cracks the sinews and cakes the brain; \
    all the subtle demonisms of life and thought; all evil, to crazy Ahab, were \
    visibly personified, and made practically assailable in Moby Dick. He piled \
    upon the whale's white hump the sum of all the general rage and hate felt by \
    his whole race from Adam down; and then, as if his chest had been a mortar, \
    he burst his hot heart's shell upon it."
]

Pretty Printing Primitive Type Arrays

Primitive type arrays SHOULD be broken up into multiple indented lines if the line is getting too long.

c1
@u16x[aa5c 5e0f e9a7 b65b 3572 96ec da16 6496 6133 5aa1 687f 9ce0 4d10 a39e 3bd3
      bf96 ad12 e64b 298f e137 a99f 5fb8 a8ca e8e7 0595 bc2f 4b64 8b0e 895d ebe7
      fb59 fdb0 1d93 5747 239d b16f 7d9c c48b 5581 13ba 19ca 6f3b 4ba9]

Pretty Printing Comments

In the event that a machine generating CTE documents wants to also output comments, the following rules apply:

Comments SHOULD have one space (u+0020) after the comment opening sequence. Multiline-style comments (/* */) SHOULD also have a space before the closing sequence.

c1
{
    // abc

    /* abc */
}

Long comments SHOULD be broken up to fit within the right margin.

c1
{
    /* When a comment gets too long to fit within the right margin, place
       the overflow on a separate lines, adjusting the indent to keep
       everything aligned. */
}

The object following a comment SHOULD be on a different line.

c1
{
    /* See list of request types in request-types.md */
    "request-type" = "ping"
}

Version History

Date Version
July 22, 2018 Draft
TBD Version 1

License

Copyright (c) 2018-2023 Karl Stenerud. All rights reserved.

Distributed under the Creative Commons Attribution License (license deed.