contributors

Authors

Reviewers

  • Mike Gionfriddo,
  • Ted Leung,
  • Hao Thai
  • Chun Xia,

Originally published May 12, 2009.
This is version 0.3, published May 19, 2009.

Introduction

In 140 chars: Twitter Data lets people embed bits of data in their tweets so that computers can read the data and do cool stuff #twitterdata

Twitter Data is a simple, open, semi-structured format for embedding machine-readable, yet human-friendly, data in messages. This data can then be transmitted, received, and interpreted in real time by powerful new kinds of applications built on the Twitter platform. Here is an example Twitter Data message:

I love the #twitterdata proposal! $vote +1

The part with the dollar sign, $vote +1, is a piece of data embedded using the Twitter Data format.

When an application knows how to read this data, it can then display it to users or send it to other applications to make Twitter an even more interesting and useful platform. You can see an example of this in the voting widget over there in the right-hand column of this page.

How it works

  1. A user (or her Twitter client) sends a Twitter message that includes embedded Twitter Data, like Watch out, just saw a #police car near San Francisco Airport $lat 37.612804 $long -122.381687
  2. This message is distributed like any other Twitter message to the user's followers
  3. The followers' Twitter clients listen for messages with embedded Twitter Data and extract data they understand. This data is presented to users, recorded, or otherwise consumed in some useful way. In this example, the Twitter client could show a map with a pin for the police car's location.
  4. Data mining applications extract Twitter Data from messages using the Twitter platform (for example, using search or the public timeline) and then process it, present it, or otherwise consume it in some way useful to humans or other applications. In this example, it would be possible to build a map showing police car locations in real time based on user reports via Twitter.

Why?

Twitter is an amazing, constantly changing stream of information, most of which is unstructured, with useful data locked up in the near-infinite complexity of human language. The inability to easily extract this data limits the usefulness of that information, particularly for applications that want to interact with humans on Twitter in interesting ways. For example, use cases such as attaching metadata about message senders or distributing shared data within a social graph are difficult to solve without using some structured data format.

When data can be formally embedded in Twitter messages, we see enormous new opportunities for data mining, social data distribution, and intelligent application behavior unlimited by lack of natural language processing technology. Best of all, the richness of this data is available to everyone, and can be sent and consumed by both humans and machines.

Goals

By proposing an embedded data format, our goal is not to turn Twitter into a mere transport layer for machine-readable data, but instead to allow semi-structured data to be mixed fluidly with normal message content. To these ends, we have chosen a syntax that conceptually resembles the use of Twitter hashtags, albeit with different syntax and semantics, and which allows humans to interact with data in a reasonably normal way.

We are publishing this proposal to invite peer review, spark useful debate, and gather consensus. In short, we think this is a good idea and hope you will too, but we need your help to vet it.

Terms

Applications
Programs that send and/or receive messages that may contain Twitter Data tuples
Message frame
A single message containing Twitter Data tuples, normally with a max length of 140 characters on Twitter. Message frames may be embedded in other messages frames, for example in the case of retweeting.
Tuple
A single pair of name and value used to send a single datum
Twitter Data
A distinct dimension of machine-readable data that can be embedded in Twitter or Twitter-like messages

Syntax

Tuples

Data is structured as simple name-value pairs of strings, called tuples, embedded in normal Twitter messages. The simplest form is the following:

$name1 value1

This example shows a single tuple, with the name "name1" and the value "value1".

Names and values are separated by one or more spaces. These spaces are not considered part of the name or the value. Values start with the first non-space character following the termination of the name with a space. Therefore, this example is equivalent to the one above despite the number of spaces between name and value:

$name1        value1

Spaces within values are literal and unescaped:

$name1 some long value

Multiple tuples can appear in a single message frame, where the value of the previous tuple is terminated by the start of a new tuple name preceeded by a space:

$name1 value1 $name2 value2

If a tuple appears at the end of the message, then the value terminator is implicit. If the tuple is embedded in the message with non-data text, the last tuple's value before the text begins must be terminated by a dollar-sign delimiter following the last character of the last value, immediately followed by a space:

some text $name1 value1 $name2 value2$ some more text

Multiple groups of tuples are allowed, as long as they are each properly terminated:

some text $name1 value1 $name2 value2$ some more text $name3 value3

If a tuple value contains the literal dollar-sign character ("$"), the literal character must be escaped by doubling the character to "$$". If non-data message text contains the literal dollar-sign character, we advise doubling the value where it may otherwise be confused with the tuple syntax.

More syntax details

Tuple names begin with a dollar sign ("$") delimiter and are terminated by the first space or non-alphanumeric character with the exceptions of underscore ("_") or as noted below. Tuple names must begin with an ASCII letter or underscore, and by convention, use camel case with the first letter lowercased. This convention helps preclude namespace collision with existing use of the dollar sign in normal messages when writing either dollar amounts or stock symbols. [TBD: How does character encoding in Twitter affect this? Is it reasonable for UTF-8 strings to be used as tuple names?]

Tuple values are terminated by the start of a new name delimiter; a single, value-trailing delimiter; or the end of the message frame.

Note, tuples without a value are considered invalid and should be excluded from processing by applications. Specifically, there is no formal representation of tuples with null values; if a tuple is present, it must have a value, however trivial. Our reasoning for this restriction is twofold: First, that such usage overlaps with the semantics of Twitter hashtags, and second, that it limits the amount of accidental interpretation by applications of non-Twitter Data message content that uses the dollar sign notation in other ways

If leading spaces are required in a value, the value should typically be quoted (with single or double quotes), or the space characters would be escaped, for example with URL encoding ("%20"). However, quotes or other encoded forms are considered part of the tuple value and interpretation of them in relation to the value rests with the receiving applications. This proposal does not specify a standard mechanism for quoting or encoding values. [TBD: Why not?]

Tuple recency

The same tuple name may appear more than once in the same message frame. If each tuple applies to a separate subject, then normal semantics apply. If all tuples apply to the same subject, then the rightmost tuple should be considered the more recent. Note that recency does not necessarily imply that a tuple value is exclusive with a prior tuple value. Depending on the semantics of the tuple and/or subject, multiple tuple values over time may be additive.

For example, in the following message frame:

$likes movies $likes Twitter

it seems obvious that the $likes tuples should be non-exclusive. Compare to these examples, in which tuples should be exclusive because they describe momentary states of the subject:

I love #twitterdata $vote +1$ but now I hate it $vote -1

driving $mph 65$, oops just hit a wall $mph 0

The interpretation and semantics of any tuple values that appear in a message frame or over time in a message stream is beyond the scope of this proposal. We expect the semantics of commonly-defined tuples with regard to exclusivity of multiple values to be addressed by community convention.

Reserved tuple names

We expect tuple names to be used by the community following community-developed conventions. However, this proposal does reserve all un-namespaced tuple names of a single letter or underscore. Specifically, the following un-namespaced tuple names are reserved and should not be used by applications:

a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, _, foo, bar

Comments on syntax

Some may question the use of the dollar-sign ("$") as a tuple delimiter. One main driver for this choice is that there is a very limited set of non-alphanumeric characters that are compatible with Twitter's search engine. Namely, Twitter search treats most non-alphanumeric characters in a special way that limits their usefulness in conjunction with this proposal. Note, this could change if Twitter works with the community to formalize use of an alternate character.

Here are some of our justifications for using "$":

  • Similar syntax to PHP and other scripting languages
  • The use of the character in this way seems to be relatively unique on Twitter and thus is available for use for encoding data
  • Compatible with Twitter search, making it possible to use for partial searches with other characters in conjunction.
  • It is human readable and doesn't interfere too much with normal readability so that Twitter Data message frames can be useful to humans as well as machines.

There are some open issues with this choice, however:

  • The dollar-sign notation is used by PHP programmers to express short code snippets on Twitter. The namespace collision may or may not be an issue over the long term. As a precaution, we have reserved the $foo and $bar tuple names because they commonly appear in code snippets.
  • The dollar-sign notation is also used by Twitter users discussing stock symbols, for example $MSFT, $ORCL, $JAVA. Usually the stock symbols are in upper case, which is part of the justification for Twitter Data to default to lowercase tuple names.

Simple namespaces

Namespacing is a key capability that allows Twitter Data tuples to be interpreted with strict, well-defined semantics. The namespace syntax is the following:

$namespace>name value

Namespaces comprise the portion of the tuple name following the name delimiter "$" and preceding the greater-than symbol (">") symbol. They follow all syntax rules as described above, and thus may not contain spaces or other non-alphanumeric characters. Only one namespace may appear in a tuple name.

Our intent is that the presence of namespaces allow the community to define more precise semantics for interpretation of tuples. It is beyond the scope of this proposal to define the semantics or content of any particular namespaces at this time.

However, this proposal does reserve all namespaces of a single letter or underscore, in addition to the "td" namespace. Specifically, the following namespaces are reserved and should not be used by applications:

a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x, y, z, _, td

Message subjects

In many cases, it is useful for data in Twitter Data messages to be interpreted relative to a general topic, or subject. A subject is a person, object, message stream, or other concrete or abstract entity to which one or more tuples in the message frame apply. As explained below, subjects may be implicitly determined by applications, or explicitly specified in the message.

More than one subject may appear in a message frame, but any given tuple is governed by only a single subject, called its dominant subject. By convention, tuples are interpreted within the context of their dominant subject, if present. A dominant subject is the subject that is closest to a tuple:

The nearest subject identifier to the left of a tuple and outside a tuple value is the dominant subject for that tuple.

where a subject identifier is either implicit or explicit as described in the sections below.

In message frames without a determinable subject, the subject is considered undefined, and tuples may be freely interpreted by any application that purports to understand them. However, there are no semantic guarantees in this case, and misinterpretation is possible. Applications should therefore be robust in handling and filtering unexpected tuple values (which is true even in the case where a subject is present).

While tuples in message frames without a subject are not by definition meant to apply to the message sender, in practice they often do. We understand that this is a very natural way to interpret subjectless tuples, but until further feedback is available from the community we prefer to leave this to applications' interpretation.

Implicit subjects

Subjects are often implicit in a message, particularly in messages sent by humans. The rule for determining the implicit subject of a message frame is straightforward:

The nearest implicit subject identifier to the left of a tuple and outside a tuple value is the dominant subject for that tuple.

where an implicit subject identifier is one of the following:

  • A hashtag, for example, #twitterdata
  • A person tag, for example,

Therefore, in the following example, the implicit subject is #twitterdata:

Hey , I like the latest #twitterdata proposal $vote +1

Implicit subjects make it very easy for humans to embed data in messages without getting bogged down in hard-to-remember and verbose formalisms. Furthermore, it makes messages with embedded data easier to read for humans, and reduces the number of characters in a message frame.

Explicit subjects

In some cases, it reduces ambiguity or is clearer to explicitly specify a subject. Usually, it will be applications sending messages with embedded data that will want to explicitly specify a subject in order to define a formal communication channel.

Subjects are specified using a tuple of the following form, comprising the reserved tuple name "$s" and a URI value, called the subject name:

$s subject_name

The subject_name may be either a URI as defined in RFC 3986, a Twitter person tag, or a Twitter hashtag. We strongly discourage use of other classes of values.

Explicit subjects follow the same dominant subject rule as implicit subjects:

The nearest explicit subject identifier to the left of a tuple and outside a tuple value is the dominant subject for that tuple.

Applications that wish to partition their message streams from other applications are strongly encouraged to use subject tuples with URI values, such as shortened URLs (for example, shortened via bit.ly), that are unlikely to collide with other casual subject name use. Such URLs also conveniently allow the application to link to itself in the messages it sends.

By convention, messages that start with the reserved subject tuple ("$s") may be considered by applications as intended for machine-only consumption. Applications that present Twitter feeds to users may elect to filter these messages from presentation.

It is beyond the scope of this proposal to define conventions for common subjects, such as @ tags as a class of subjects, or specific hashtags. We will leave this task to the community.

Note, the use of subjects potentially reduces the amount of namespacing, thus saving valuable characters, and allows messages to be filtered more efficiently by message recipients. In this sense, subjects might be considered a default namespace for all tuples within a message frame, though this is not strictly true. Furthermore, subjects may be appealing because they are more unique and terse compared to simple namespaces because the space of subject values is syntactically larger than that of simple namespaces. However, namespaces and subjects are completely compatible and will generally be used in conjunction with one another.

Other Considerations

Retweeting

Special consideration is necessary when considering the semantics of data embedded in retweeted messages. Ideally, retweeting should not change the interpretation of retweeted message frames. The purpose of retweeting is to propogate a message through a different graph of receivers, and so the central question is whether that instance of a message should be considered separate from the original instance, and thus whether it should be interpreted independently from the original. We will discuss this topic more thoroughly based on use cases for retweeted data in a future version of this proposal.

The determination of a subject for a message is somewhat more subtle in the case of retweeted messages. For messages that either implicitly or explicitly specify a subject, retweeting has no effect on the interpretation of the message frame. However, in the case of subjectless messages, the act of retweeting normally inserts a subject with the inclusion of a person tag of the original author.

As described above, a subjectless message frame does not automatically or necessarily apply to the message sender. We understand that this is an incongruity that may be addressed by either special casing the processing of retweeted messages, or by simply acknowledging that subjectless messages probably apply to message senders and thus the semantics of subject determination are neatly compatible with retweeting. We would appreciate community feedback before making a final proposal.

Role and function of hashtags

Use of hashtags in Twitter Data is largely unchanged. If hashtags appear in tuple values, they may be interepreted as normal hashtags in the normal way by humans and user agents, and have undefined semantics in terms of this proposal. By contrast, hashtags may not appear as part of tuple names.

Hashtags will often be use as subjects of messages, which is semantically consistent with their intended purpose.

Binary data

This proposal is not suited to use cases that require streaming, binary data, or large amounts of data to be exchanged. In particular, rate limits of messages on Twitter combined with the limited message size make Twitter Data unsuitable for transferring significant amounts of data at high speeds.

In general, we discourage applications from using binary data with Twitter Data, largely because it harms interoperability and is inconvenient for users using Twitter to send human-readable messages. However, binary data is unavoidable in some cases, and may be less ugly than the equivalent human-readable serialization. If binary data is sent, it should be Base64 encoded.

Data size

A single tuple may not span more than one message frame of 140 characters. However, multiple tuples may be included in a single message frame, with the requirement that all included tuples fit collectively within the message frame size limit (on Twitter, 140 characters). Note, we may introduce a means of frame spanning in a later proposal.

This specification does not specify a way to determine if tuple values are truncated at the end of a message frame because the requirement of terminating the set of tuples with a delimiter is optional. Applications that receive tuples must be aware of this restriction and ensure that they check for invalid values. Applications that send tuples should instead attempt to send additional message frames with tuples that would otherwise be truncated.

Atomicity and transactional semantics

The usefulness and novelty of Twitter Data rests on the ability for multiple messages containing varying data to be delivered over time, in what we call message streams. Message streams are a virtual consolidation of multiple messages around specific criteria, for example a person, subject, or a search query. Note that messages may appear in multiple message streams, in differing order.

The order of appearance of tuples in a message stream is undefined with respect to this proposal, though it is most common for them to be ordered in time, with the latest message at the head of the stream as we nominally see in Twitter.

Data in message frames are intended to be non-atomic and non-transactional. That is, there is no mechanism to determine whether a collection of tuples should be considered one atomic group. Said another way, there is no mechanism to specify the semantics of groups of tuples, particularly across message frames.

Instead, applications should typically consider the last tuple of a given name as containing the most recent data with respect to a given message stream.

This looseness allows data to be streamed more efficiently through Twitter's low-bandwidth messaging platform. Duplicate or non-relevant values need not be respecified in order to help applications determine the semantics of collections of tuples.

Note, because of the lack of restriction on tuple delivery order, applications sending message frames are free to optimize sending of multiple tuples by arranging them to fit most efficiently across the fewest number of message frames without truncation.

Semantic web

We have designed Twitter Data with an eye to layering additional semantic structures on top. We will discuss these possibilities in a later version of this proposal.

Applicability

While its name would seem to indicate a focus only on Twitter, Twitter Data may also be used on similar messaging services, over instant messaging (particularly in the case of multicast conferences), email, SMS, or any other point-to-point, broadcast, or multicast messaging infrastructure, with or without message size restrictions.

Because of the constraints of Twitter message sizes, Twitter Data is also intended to be terse and compact without sacrificing human readability, and to avoid overwhelming normal Twitter streams with ugly, encoded data intended only for machines. Because of its terseness, it is useful over low-bandwidth, high-latency, and mobile networks.

Furthermore, because of the human-friendly syntax, Twitter Data is suitable to be read, injected, and debugged by humans, in the same vein as HTTP and JSON, making it a convenient, robust, and flexible data representation format.