/toml

Tom's Obvious, Minimal Language

MIT LicenseMIT

TOML Logo

TOML

Tom's Obvious, Minimal Language.

By Tom Preston-Werner.

Latest tagged version: v0.5.0.

NOTE: The master branch of this repository tracks the very latest development and may contain features and changes that do not exist on any released version. To find the spec for a specific version, look in the versions subdirectory.

As of version 0.5.0, TOML should be considered extremely stable. The goal is for version 1.0.0 to be backwards compatible (as much as humanly possible) with version 0.5.0. All implementations are strongly encouraged to become 0.5.0 compatible so that the transition to 1.0.0 will be simple when that happens.

Objectives

TOML aims to be a minimal configuration file format that's easy to read due to obvious semantics. TOML is designed to map unambiguously to a hash table. TOML should be easy to parse into data structures in a wide variety of languages.

Table of contents

Example

# This is a TOML document.

title = "TOML Example"

[owner]
name = "Tom Preston-Werner"
dob = 1979-05-27T07:32:00-08:00 # First class dates

[database]
server = "192.168.1.1"
ports = [ 8001, 8001, 8002 ]
connection_max = 5000
enabled = true

[servers]

  # Indentation (tabs and/or spaces) is allowed but not required
  [servers.alpha]
  ip = "10.0.0.1"
  dc = "eqdc10"

  [servers.beta]
  ip = "10.0.0.2"
  dc = "eqdc10"

[clients]
data = [ ["gamma", "delta"], [1, 2] ]

# Line breaks are OK when inside arrays
hosts = [
  "alpha",
  "omega"
]

Spec

  • TOML is case sensitive.
  • A TOML file must be a valid UTF-8 encoded Unicode document.
  • Whitespace means tab (0x09) or space (0x20).
  • Newline means LF (0x0A) or CRLF (0x0D0A).

Comment

A hash symbol marks the rest of the line as a comment.

# This is a full-line comment
key = "value" # This is a comment at the end of a line

Key/Value Pair

The primary building block of a TOML document is the key/value pair.

Keys are on the left of the equals sign and values are on the right. Whitespace is ignored around key names and values. The key, equals sign, and value must be on the same line (though some values can be broken over multiple lines).

key = "value"

Values must be of the following types: String, Integer, Float, Boolean, Datetime, Array, or Inline Table. Unspecified values are invalid.

key = # INVALID

Keys

A key may be either bare, quoted or dotted.

Bare keys may only contain ASCII letters, ASCII digits, underscores, and dashes (A-Za-z0-9_-). Note that bare keys are allowed to be composed of only ASCII digits, e.g. 1234, but are always interpreted as strings.

key = "value"
bare_key = "value"
bare-key = "value"
1234 = "value"

Quoted keys follow the exact same rules as either basic strings or literal strings and allow you to use a much broader set of key names. Best practice is to use bare keys except when absolutely necessary.

"127.0.0.1" = "value"
"character encoding" = "value"
"ʎǝʞ" = "value"
'key2' = "value"
'quoted "value"' = "value"

A bare key must be non-empty, but an empty quoted key is allowed (though discouraged).

= "no key name"  # INVALID
"" = "blank"     # VALID but discouraged
'' = 'blank'     # VALID but discouraged

Dotted keys are a sequence of bare or quoted keys joined with a dot. This allows for grouping similar properties together:

name = "Orange"
physical.color = "orange"
physical.shape = "round"
site."google.com" = true

In JSON land, that would give you the following structure:

{
  "name": "Orange",
  "physical": {
    "color": "orange",
    "shape": "round"
  },
  "site": {
    "google.com": true
  }
}

Whitespace around dot-separated parts is ignored, however, best practice is to not use any extraneous whitespace.

Defining a key multiple times is invalid.

# DO NOT DO THIS
name = "Tom"
name = "Pradyun"

As long as a key hasn't been directly defined, you may still write to it and to names within it.

a.b.c = 1
a.d = 2
# THIS IS INVALID
a.b = 1
a.b.c = 2

String

There are four ways to express strings: basic, multi-line basic, literal, and multi-line literal. All strings must contain only valid UTF-8 characters.

Basic strings are surrounded by quotation marks. Any Unicode character may be used except those that must be escaped: quotation mark, backslash, and the control characters (U+0000 to U+001F, U+007F).

str = "I'm a string. \"You can quote me\". Name\tJos\u00E9\nLocation\tSF."

For convenience, some popular characters have a compact escape sequence.

\b         - backspace       (U+0008)
\t         - tab             (U+0009)
\n         - linefeed        (U+000A)
\f         - form feed       (U+000C)
\r         - carriage return (U+000D)
\"         - quote           (U+0022)
\\         - backslash       (U+005C)
\uXXXX     - unicode         (U+XXXX)
\UXXXXXXXX - unicode         (U+XXXXXXXX)

Any Unicode character may be escaped with the \uXXXX or \UXXXXXXXX forms. The escape codes must be valid Unicode scalar values.

All other escape sequences not listed above are reserved and, if used, TOML should produce an error.

Sometimes you need to express passages of text (e.g. translation files) or would like to break up a very long string into multiple lines. TOML makes this easy.

Multi-line basic strings are surrounded by three quotation marks on each side and allow newlines. A newline immediately following the opening delimiter will be trimmed. All other whitespace and newline characters remain intact.

str1 = """
Roses are red
Violets are blue"""

TOML parsers should feel free to normalize newline to whatever makes sense for their platform.

# On a Unix system, the above multi-line string will most likely be the same as:
str2 = "Roses are red\nViolets are blue"

# On a Windows system, it will most likely be equivalent to:
str3 = "Roses are red\r\nViolets are blue"

For writing long strings without introducing extraneous whitespace, use a "line ending backslash". When the last non-whitespace character on a line is a \, it will be trimmed along with all whitespace (including newlines) up to the next non-whitespace character or closing delimiter. All of the escape sequences that are valid for basic strings are also valid for multi-line basic strings.

# The following strings are byte-for-byte equivalent:
str1 = "The quick brown fox jumps over the lazy dog."

str2 = """
The quick brown \


  fox jumps over \
    the lazy dog."""

str3 = """\
       The quick brown \
       fox jumps over \
       the lazy dog.\
       """

Any Unicode character may be used except those that must be escaped: backslash and the control characters (U+0000 to U+001F, U+007F). Quotation marks need not be escaped unless their presence would create a premature closing delimiter.

If you're a frequent specifier of Windows paths or regular expressions, then having to escape backslashes quickly becomes tedious and error prone. To help, TOML supports literal strings which do not allow escaping at all.

Literal strings are surrounded by single quotes. Like basic strings, they must appear on a single line:

# What you see is what you get.
winpath  = 'C:\Users\nodejs\templates'
winpath2 = '\\ServerX\admin$\system32\'
quoted   = 'Tom "Dubs" Preston-Werner'
regex    = '<\i\c*\s*>'

Since there is no escaping, there is no way to write a single quote inside a literal string enclosed by single quotes. Luckily, TOML supports a multi-line version of literal strings that solves this problem.

Multi-line literal strings are surrounded by three single quotes on each side and allow newlines. Like literal strings, there is no escaping whatsoever. A newline immediately following the opening delimiter will be trimmed. All other content between the delimiters is interpreted as-is without modification.

regex2 = '''I [dw]on't need \d{2} apples'''
lines  = '''
The first newline is
trimmed in raw strings.
   All other whitespace
   is preserved.
'''

Control characters other than tab are not permitted in a literal string. Thus, for binary data it is recommended that you use Base64 or another suitable ASCII or UTF-8 encoding. The handling of that encoding will be application specific.

Integer

Integers are whole numbers. Positive numbers may be prefixed with a plus sign. Negative numbers are prefixed with a minus sign.

int1 = +99
int2 = 42
int3 = 0
int4 = -17

For large numbers, you may use underscores between digits to enhance readability. Each underscore must be surrounded by at least one digit on each side.

int5 = 1_000
int6 = 5_349_221
int7 = 1_2_3_4_5     # VALID but discouraged

Leading zeros are not allowed. Integer values -0 and +0 are valid and identical to an unprefixed zero.

Non-negative integer values may also be expressed in hexadecimal, octal, or binary. In these formats, leading + is not allowed and leading zeros are allowed (after the prefix). Hex values are case insensitive. Underscores are allowed between digits (but not between the prefix and the value).

# hexadecimal with prefix `0x`
hex1 = 0xDEADBEEF
hex2 = 0xdeadbeef
hex3 = 0xdead_beef

# octal with prefix `0o`
oct1 = 0o01234567
oct2 = 0o755 # useful for Unix file permissions

# binary with prefix `0b`
bin1 = 0b11010110

64 bit (signed long) range expected (−9,223,372,036,854,775,808 to 9,223,372,036,854,775,807).

Float

Floats should be implemented as IEEE 754 binary64 values.

A float consists of an integer part (which follows the same rules as decimal integer values) followed by a fractional part and/or an exponent part. If both a fractional part and exponent part are present, the fractional part must precede the exponent part.

# fractional
flt1 = +1.0
flt2 = 3.1415
flt3 = -0.01

# exponent
flt4 = 5e+22
flt5 = 1e6
flt6 = -2E-2

# both
flt7 = 6.626e-34

A fractional part is a decimal point followed by one or more digits.

An exponent part is an E (upper or lower case) followed by an integer part (which follows the same rules as decimal integer values).

Similar to integers, you may use underscores to enhance readability. Each underscore must be surrounded by at least one digit.

flt8 = 224_617.445_991_228

Float values -0.0 and +0.0 are valid and should map according to IEEE 754.

Special float values can also be expressed. They are always lowercase.

# infinity
sf1 = inf  # positive infinity
sf2 = +inf # positive infinity
sf3 = -inf # negative infinity

# not a number
sf4 = nan  # actual sNaN/qNaN encoding is implementation specific
sf5 = +nan # same as `nan`
sf6 = -nan # valid, actual encoding is implementation specific

Boolean

Booleans are just the tokens you're used to. Always lowercase.

bool1 = true
bool2 = false

Offset Date-Time

To unambiguously represent a specific instant in time, you may use an RFC 3339 formatted date-time with offset.

odt1 = 1979-05-27T07:32:00Z
odt2 = 1979-05-27T00:32:00-07:00
odt3 = 1979-05-27T00:32:00.999999-07:00

For the sake of readability, you may replace the T delimiter between date and time with a space (as permitted by RFC 3339 section 5.6).

odt4 = 1979-05-27 07:32:00Z

The precision of fractional seconds is implementation specific, but at least millisecond precision is expected. If the value contains greater precision than the implementation can support, the additional precision must be truncated, not rounded.

Local Date-Time

If you omit the offset from an RFC 3339 formatted date-time, it will represent the given date-time without any relation to an offset or timezone. It cannot be converted to an instant in time without additional information. Conversion to an instant, if required, is implementation specific.

ldt1 = 1979-05-27T07:32:00
ldt2 = 1979-05-27T00:32:00.999999

The precision of fractional seconds is implementation specific, but at least millisecond precision is expected. If the value contains greater precision than the implementation can support, the additional precision must be truncated, not rounded.

Local Date

If you include only the date portion of an RFC 3339 formatted date-time, it will represent that entire day without any relation to an offset or timezone.

ld1 = 1979-05-27

Local Time

If you include only the time portion of an RFC 3339 formatted date-time, it will represent that time of day without any relation to a specific day or any offset or timezone.

lt1 = 07:32:00
lt2 = 00:32:00.999999

The precision of fractional seconds is implementation specific, but at least millisecond precision is expected. If the value contains greater precision than the implementation can support, the additional precision must be truncated, not rounded.

Array

Arrays are square brackets with values inside. Whitespace is ignored. Elements are separated by commas. Data types may not be mixed (different ways to define strings should be considered the same type, and so should arrays with different element types).

arr1 = [ 1, 2, 3 ]
arr2 = [ "red", "yellow", "green" ]
arr3 = [ [ 1, 2 ], [3, 4, 5] ]
arr4 = [ "all", 'strings', """are the same""", '''type''']
arr5 = [ [ 1, 2 ], ["a", "b", "c"] ]

arr6 = [ 1, 2.0 ] # INVALID

Arrays can also be multiline. A terminating comma (also called trailing comma) is ok after the last value of the array. There can be an arbitrary number of newlines and comments before a value and before the closing bracket.

arr7 = [
  1, 2, 3
]

arr8 = [
  1,
  2, # this is ok
]

Table

Tables (also known as hash tables or dictionaries) are collections of key/value pairs. They appear in square brackets on a line by themselves. You can tell them apart from arrays because arrays are only ever values.

[table]

Under that, and until the next table or EOF are the key/values of that table. Key/value pairs within tables are not guaranteed to be in any specific order.

[table-1]
key1 = "some string"
key2 = 123

[table-2]
key1 = "another string"
key2 = 456

Naming rules for tables are the same as for keys (see definition of Keys above).

[dog."tater.man"]
type.name = "pug"

In JSON land, that would give you the following structure:

{ "dog": { "tater.man": { "type": { "name": "pug" } } } }

Whitespace around the key is ignored, however, best practice is to not use any extraneous whitespace.

[a.b.c]            # this is best practice
[ d.e.f ]          # same as [d.e.f]
[ g .  h  . i ]    # same as [g.h.i]
[ j . "ʞ" . 'l' ]  # same as [j."ʞ".'l']

You don't need to specify all the super-tables if you don't want to. TOML knows how to do it for you.

# [x] you
# [x.y] don't
# [x.y.z] need these
[x.y.z.w] # for this to work

Empty tables are allowed and simply have no key/value pairs within them.

Like keys, you cannot define any table more than once. Doing so is invalid.

# DO NOT DO THIS

[a]
b = 1

[a]
c = 2
# DO NOT DO THIS EITHER

[a]
b = 1

[a.b]
c = 2

Inline Table

Inline tables provide a more compact syntax for expressing tables. They are especially useful for grouped data that can otherwise quickly become verbose. Inline tables are enclosed in curly braces { and }. Within the braces, zero or more comma separated key/value pairs may appear. Key/value pairs take the same form as key/value pairs in standard tables. All value types are allowed, including inline tables.

Inline tables are intended to appear on a single line. No newlines are allowed between the curly braces unless they are valid within a value. Even so, it is strongly discouraged to break an inline table onto multiples lines. If you find yourself gripped with this desire, it means you should be using standard tables.

name = { first = "Tom", last = "Preston-Werner" }
point = { x = 1, y = 2 }
animal = { type.name = "pug" }

The inline tables above are identical to the following standard table definitions:

[name]
first = "Tom"
last = "Preston-Werner"

[point]
x = 1
y = 2

[animal]
type.name = "pug"

Array of Tables

The last type that has not yet been expressed is an array of tables. These can be expressed by using a table name in double brackets. Each table with the same double bracketed name will be an element in the array. The tables are inserted in the order encountered. A double bracketed table without any key/value pairs will be considered an empty table.

[[products]]
name = "Hammer"
sku = 738594937

[[products]]

[[products]]
name = "Nail"
sku = 284758393
color = "gray"

In JSON land, that would give you the following structure.

{
  "products": [
    { "name": "Hammer", "sku": 738594937 },
    { },
    { "name": "Nail", "sku": 284758393, "color": "gray" }
  ]
}

You can create nested arrays of tables as well. Just use the same double bracket syntax on sub-tables. Each double-bracketed sub-table will belong to the most recently defined table element above it.

[[fruit]]
  name = "apple"

  [fruit.physical]
    color = "red"
    shape = "round"

  [[fruit.variety]]
    name = "red delicious"

  [[fruit.variety]]
    name = "granny smith"

[[fruit]]
  name = "banana"

  [[fruit.variety]]
    name = "plantain"

The above TOML maps to the following JSON.

{
  "fruit": [
    {
      "name": "apple",
      "physical": {
        "color": "red",
        "shape": "round"
      },
      "variety": [
        { "name": "red delicious" },
        { "name": "granny smith" }
      ]
    },
    {
      "name": "banana",
      "variety": [
        { "name": "plantain" }
      ]
    }
  ]
}

Attempting to append to a statically defined array, even if that array is empty or of compatible type, must produce an error at parse time.

# INVALID TOML DOC
fruit = []

[[fruit]] # Not allowed

Attempting to define a normal table with the same name as an already established array must produce an error at parse time.

# INVALID TOML DOC
[[fruit]]
  name = "apple"

  [[fruit.variety]]
    name = "red delicious"

  # This table conflicts with the previous table
  [fruit.variety]
    name = "granny smith"

You may also use inline tables where appropriate:

points = [ { x = 1, y = 2, z = 3 },
           { x = 7, y = 8, z = 9 },
           { x = 2, y = 4, z = 8 } ]

Filename Extension

TOML files should use the extension .toml.

MIME Type

When transferring TOML files over the internet, the appropriate MIME type is application/toml.

Comparison with Other Formats

In some ways TOML is very similar to JSON: simple, well-specified, and maps easily to ubiquitous data types. JSON is great for serializing data that will mostly be read and written by computer programs. Where TOML differs from JSON is its emphasis on being easy for humans to read and write. Comments are a good example: they serve no purpose when data is being sent from one program to another, but are very helpful in a configuration file that may be edited by hand.

The YAML format is oriented towards configuration files just like TOML. For many purposes, however, YAML is an overly complex solution. TOML aims for simplicity, a goal which is not apparent in the YAML specification: http://www.yaml.org/spec/1.2/spec.html

The INI format is also frequently used for configuration files. The format is not standardized, however, and usually does not handle more than one or two levels of nesting.

Get Involved

Documentation, bug reports, pull requests, and all other contributions are welcome!

Wiki

We have an Official TOML Wiki that catalogs the following:

  • Projects using TOML
  • Implementations
  • Validators
  • Language agnostic test suite for TOML decoders and encoders
  • Editor support
  • Encoders
  • Converters

Please take a look if you'd like to view or add to that list. Thanks for being a part of the TOML community!