Difference between revisions of "LLSD"

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| vertical tab || \v
| vertical tab || \v
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== Example Notation Output ==
This is an excerpt from an agent request to enter a regiona serialized as notation:
<pre>
[
  {'destination':'http://secondlife.com'},
  {'version':i1},
  {
    'agent_id':u3c115e51-04f4-523c-9fa6-98aff1034730,
    'session_id':u2c585cec-038c-40b0-b42e-a25ebab4d132,
    'circuit_code':i1075,
    'first_name':'Phoenix',
    'last_name':'Linden',
    'position':[r70.9247,r254.378,r38.7304],
    'look_at':[r-0.043753,r-0.999042,r0],
    'granters':[ua2e76fcd-9360-4f6d-a924-000000000003],
    'attachment_data':
    [
      {
        'attachment_point':i2,
        'item_id':ud6852c11-a74e-309a-0462-50533f1ef9b3,
        'asset_id':uc69b29b1-8944-58ae-a7c5-2ca7b23e22fb
      },
      {
        'attachment_point':i10,
        'item_id':uff852c22-a74e-309a-0462-50533f1ef900,
        'asset_id':u5868dd20-c25a-47bd-8b4c-dedc99ef9479
      }
    ]
  }
]
</pre>


= Guidelines =
= Guidelines =

Revision as of 09:06, 13 April 2007

The LLSD flexible data system

The following text is from the comments in the source of the file: linden\indra\common\llsd.cpp

Summary

LLSD provides a flexible data system similar to the data facilities of dynamic languages like Perl and Python. It is created to support exchange of structured data between loosly coupled systems. (Here, "loosly coupled" means not compiled together into the same module.)

Data in such exchanges must be highly tolerant of changes on either side such as: - recompilation - implementation in a different langauge - addition of extra parameters - execution of older versions (with fewer parameters)

To this aim, the C++ API of LLSD strives to be very easy to use, and to default to "the right thing" whereever possible. It is extremely tolerant of errors and unexpected situations.

The fundamental class is LLSD. LLSD is a value holding object. It holds one value that is either undefined, one of the scalar types, or a map or an array. LLSD objects have value semantics (copying them copies the value, though it can be considered efficient, due to sharing.), and mutable.

Undefined is the singular value given to LLSD objects that are not initialized with any data. It is also used as the return value for operations that return an LLSD,

The scalar data types are:

  • Boolean - true or false
  • Integer - a 32 bit signed integer
  • Real - a 64 IEEE 754 floating point value
  • UUID - a 128 unique value
  • String - a sequence of zero or more Unicode chracters
  • Date - an absolute point in time, UTC, with resolution to the second
  • URI - a String that is a URI
  • Binary - a sequence of zero or more octets (unsigned bytes)

A map is a dictionary mapping String keys to LLSD values. The keys are unique within a map, and have only one value (though that value could be an LLSD array).

An array is a sequence of zero or more LLSD values.

Scalar Accessors

Function: Fetch a scalar value, converting if needed and possible.

Conversion among the basic types, Boolean, Integer, Real and String, is fully defined. Each type can be converted to another with a reasonable interpretation. These conversions can be used as a convenience even when you know the data is in one format, but you want it in another. Of course, many of these conversions lose information.

Note: These conversions are not the same as Perl's. In particular, when converting a String to a Boolean, only the empty string converts to false. Converting the String "0" to Boolean results in true.

Conversion to and from UUID, Date, and URI is only defined to and from String. Conversion is defined to be information preserving for valid values of those types. These conversions can be used when one needs to convert data to or from another system that cannot handle these types natively, but can handle strings.

Conversion to and from Binary isn't defined.

Conversion of the Undefined value to any scalar type results in a reasonable null or zero value for the type.


Automatic Cast Protection

These are not implemented on purpose. Without them, C++ can perform some conversions that are clearly not what the programmer intended.

If you get a linker error about these being missing, you have made mistake in your code. DO NOT IMPLEMENT THESE FUNCTIONS as a fix.

All of thse problems stem from trying to support char* in LLSD or in std::string. There are too many automatic casts that will lead to using an arbitrary pointer or scalar type to std::string.

Attributes and Data

Attributes are only used for encoding parser and formatting instructions. The data in the elements is always data.

Root Element

The root element is llsd. The root must have only one child element which can be any container or atomic type.

Atomic Types

Each atomic type represents one value with type information. An atomic does not have a name, but may have attributes to specify format or processing considerations for the parser. Consumers of atomics are encouraged to massage the data into the preferred native representation, but further serialization should honor the original type information if possible.

undefined

The undefined type is a placeholder to indicate something is there, but it has no value, and cannot be converted to any other atomic type. Though limited in this way, an undefined is still considered a first-class atomic, and is expected to behave like any other atomic structured data type at runtime.

Serialization example

<undef />

boolean

A true or false value.

Conversion

type rules
boolean unity
integer true => 1, false => 0
real true => 1.0, false => 0.0
uuid n/a
string 'true', 'false'
binary one byte us-ascii where true => 1, false => 0
date n/a
uri n/a

Serialization examples

<!-- true -->
<boolean>1</boolean>
<boolean>true</boolean>

<!-- false -->
<boolean>0</boolean>
<boolean>false</boolean>
<boolean />

integer

A signed integer value with a representation of 64 bits.

Conversion

type rules
boolean 0 => false, all other values => true
integer unity
real closest representable number
uuid n/a
string human readable string
binary 8 byte network byte order representation
date seconds since epoch
uri n/a

Serialization examples

<integer>289343</integer>
<integer>-3</integer>
<integer /> <!-- zero -->

real

A 64 bit double as defined by IEEE.

Conversion

type rules
boolean exactly 0 => false, all other values => true
integer rounded to closest representable number
real unity
uuid n/a
string human readable string
binary 8 byte network byte order representation
date seconds since epoch
uri n/a

Serialization examples

<real>-0.28334</real>
<real>2983287453.3848387</real>
<real /> <!-- exactly zero -->

uuid

A 128 byte unsigned integer.

Conversion

type rules
boolean null uuid => false, all other values => true
integer n/a
real n/a
uuid unity
string standard 8-4-4-4-12 serialization format
binary 16 byte raw representation
date n/a
uri n/a

Serialization examples

<uuid>d7f4aeca-88f1-42a1-b385-b9db18abb255</uuid>
<uuid /> <!-- null uuid '00000000-0000-0000-0000-000000000000' -->

string

A simple string of any character data which is intended to be human comprehensible.

Conversion

type rules
boolean empty => false, all other values => true
integer A simple conversion of the initial characters to an integer
real A simple conversion of the initial characters to a real number
uuid A valid 8-4-4-4-12 is converted to a uuid, all other values => null uuid
string unity
binary raw representation of the characters
date An interpretation of the string as a date
uri An interpretation of the string as a link

Serialization examples

<string>The quick brown fox jumped over the lazy dog.</string>
<string>540943c1-7142-4fdd-996f-fc90ed5dd3fa</string>
<string /> <!-- empty string -->

binary data

A chunk of binary data. The serialization format is allowed to specify an encoding. Parsers must support base64 encoding. Parsers may support base16 and base85.

Conversion

type rules
boolean empty => false, all other values => true
integer len < 8 => 0, otherwise first eight bytes are interpreted as a network byte order integer
real len < 8 => 0, otherwise first eight bytes are interpreted as a network byte order double
uuid len < 16 => null uuid, otherwise first sixteen bytes are interpreted as the raw binary uuid
string the raw binary data interpreted as utf-8 character data
binary unity
date n/a
uri the raw binary data interpreted as a utf-8 serialized link

Serialization examples

<binary encoding="base64">cmFuZG9t</binary> <!-- base 64 encoded binary data -->
<binary>dGhlIHF1aWNrIGJyb3duIGZveA==</binary> <!-- base 64 encoded binary data is default -->
<binary /> <!-- empty binary blob -->

date

A specific point in time. Intervals or relative dates are not supported. The serialization and parser only understand ISO-8601 numeric encoding in UTC. The time may be omitted which will be interpreted as midnight at the start of the day.

Conversion

type rules
boolean n/a
integer seconds since epoch
real seconds since epoch
uuid n/a
string standard serialization format
binary n/a
date unity
uri n/a

Serialization examples

<date>2006-02-01T14:29:53Z</date>
<date /> <!-- epoch -->

uri

A link to an external resource. The data is expected to conform to rfc 2396 for interpretation, meaning, serialization, and deserialization.

Conversion

type rules
boolean n/a
integer n/a
real n/a
uuid n/a
string standard serialization format
binary n/a
date n/a
uri unity

Serialization examples

<uri>http://sim956.agni.lindenlab.com:12035/runtime/agents</uri>
<uri /> <!-- an empty link -->

Containers

Containers is a special data type which can contain any other data type including other containers.

map

A map of key and value pairs where key ordering is unspecified and keys are unique. The key is always interpreted as a character string and any character string is acceptable. If there are any elements in the map, it is serialized as a key followed by an atomic or container value. For every key, there must be one value. Well formed and valid serialized maps may contain more non-unique keys. When a deserialized, the implementation should choose one of the the value objects, but that choice is not specified.

Serialization example

<map>
 <key>foo</key>
 <string>bar</string>
 <key>agent info</key>
 <map>
  <key>agent_id</key>
  <uuid>93c73b16-cd86-434d-8b4a-76e12eee950a</uuid>
  <key>name</key>
  <string>testtest tester</string>
 </map>
</map>

array

An ordered collection of data members. Any member can be any atomic or container type.

Serialization example

<array>
 <real>7343.0194</real>
 <array>
  <map>
   <key>offset</key>
   <integer>9847</integer>
  </map>
  <string>da boom</string>
 </array>
</array>

xml-llsd DTD

<!DOCTYPE llsd [
<!ELEMENT llsd (DATA)>
<!ELEMENT DATA (ATOMIC|map|array)>
<!ELEMENT ATOMIC (undef|boolean|integer|real|uuid|string|date|uri|binary)>
<!ELEMENT KEYDATA (key,DATA)>
<!ELEMENT key (#PCDATA)>
<!ELEMENT map (KEYDATA*)>
<!ELEMENT array (DATA*)>
<!ELEMENT undef (EMPTY)>
<!ELEMENT boolean (#PCDATA)>
<!ELEMENT integer (#PCDATA)>
<!ELEMENT real (#PCDATA)>
<!ELEMENT uuid (#PCDATA)>
<!ELEMENT string (#PCDATA)>
<!ELEMENT date (#PCDATA)>
<!ELEMENT uri (#PCDATA)>
<!ELEMENT binary (#PCDATA)>

<!ATTLIST string xml:space (default|preserve) 'preserve'>
<!ATTLIST binary encoding CDATA "base64">
]>

Example XML Output

This is a sample from a recently running sim:

$ curl http://localhost:12035/runtime/statistics
<?xml version="1.0" encoding="UTF-8"?>
<llsd>
<map>
<key>region_id</key>
<uuid>67153d5b-3659-afb4-8510-adda2c034649</uuid>
<key>scale</key>
<string>one minute</string>
<key>simulator statistics</key>
<map>
<key>time dilation</key><real>0.9878624</real>
<key>sim fps</key><real>44.38898</real>
<key>pysics fps</key><real>44.38906</real>
<key>agent updates per second</key><real>nan</real>
 <key>lsl instructions per second</key><real>0</real>
<key>total task count</key><real>4</real>
<key>active task count</key><real>0</real>
<key>active script count</key><real>4</real>
<key>main agent count</key><real>0</real>
<key>child agent count</key><real>0</real>
<key>inbound packets per second</key><real>1.228283</real>
<key>outbound packets per second</key><real>1.277508</real>
<key>pending downloads</key><real>0</real>
<key>pending uploads</key><real>0.0001096525</real>
<key>frame ms</key><real>0.7757886</real>
<key>net ms</key><real>0.3152919</real>
<key>sim other ms</key><real>0.1826937</real>
<key>sim physics ms</key><real>0.04323055</real>
<key>agent ms</key><real>0.01599029</real>
<key>image ms</key><real>0.01865955</real>
<key>script ms</key><real>0.1338836</real>
</map>
</map>
</llsd>

Binary Serialization

We also have support for binary serialization and deserialization in c++ and python. The binary format is useful when dealing where optimal parse time is necessary. Binary LLSD is the binary llsd prefix followed by a single LLSD element of any type.

<?llsd/binary?>\n
Binary element serialization
type serialization notes
undef '!'
true '1'
false '0'
integer 'i' + htonl(value)
real 'r' + htond(value)
uuid 'u' + uuid uuid is 16 bytes
binary 'b' + htonl(binary.size()) + binary
string 's' + htonl(string.size()) + string notation serialization is considered valid
uri 'l' + htonl(uri.size()) + uri
date 'd' + htond(seconds_since_epoch)
array '[' + htonl(array.length()) + (child0, child1, ...) + ']' order is always preserved
map '{' + htonl(map.length()) + ((key0,value0), (key1, value1), ...)+ '}' order is not always preserved.

size() is a byte count.

length() is a child count.

htonl() is a function to generate a 4 byte network byte order integer.

htond() is a function to generate an 8 byte network byte order double.

Notation Serialization

We also have support for a serialization format meant for human readability. Parsing and formatting are currently only available in c++. Notation LLSD is the notation llsd prefix followed by a single LLSD element of any type.

<?llsd/notation?>\n
Binary element serialization
type serialization notes
undef '!'
true 't' | 'T' | 'true' | 'TRUE'
false 'f' | 'F' | 'false' | 'FALSE'
integer 'i' str(value)
real 'r' str(value)
uuid 'u' str(uuid)
binary 'b(' str(size) ')' raw_data Base 16 and 64 encodings are supported.
string " escaped_string " | ' escaped_string ' | 's(' str(size) ')' raw_string When using single quotes, double quotes do not need escaping and vice versa.
uri 'l"' escaped_uri '"' See rfc 1738 for encoding rules.
date 'd"' YYYY-MM-DD 'T' HH:MM:SS [.FF] 'Z"' Fractional seconds are optional
array '[' object0 ',' object1 ',' ... ']' order is always preserved
map '{' string0:object0 ',' string1:object1 ',' ... '}' order is not always preserved. The string is any supported string serialization format

String Escaping

Strings which contain non-printable characters serialized with quotes or double quotes require escaping. If a single quote delimited string contains single quotes, those must be escaped. If a double quote delimited string contains double quotes, those must be escaped.

The most generic escaping is to specify a hex value of the byte after a literal backslash and character 'x'. This can be used for any character and is required for all non-printable characters which do not have an abbreviation. For example:

 \x0C

The easiest way to escape a printable character is to prepend it with a backslash. For example:

"And then he said, \"I have nothing more to say on the subject.\""

Common non-printable characters have short-hand abbreviations

Notation abbreviations
character serialization
alert/bell \a
backspace \b
form feed \f
newline \n
carriage return \r
horizontal tab \t
vertical tab \v

Example Notation Output

This is an excerpt from an agent request to enter a regiona serialized as notation:

[
  {'destination':'http://secondlife.com'}, 
  {'version':i1}, 
  {
    'agent_id':u3c115e51-04f4-523c-9fa6-98aff1034730, 
    'session_id':u2c585cec-038c-40b0-b42e-a25ebab4d132, 
    'circuit_code':i1075, 
    'first_name':'Phoenix', 
    'last_name':'Linden',
    'position':[r70.9247,r254.378,r38.7304], 
    'look_at':[r-0.043753,r-0.999042,r0], 
    'granters':[ua2e76fcd-9360-4f6d-a924-000000000003],
    'attachment_data':
    [
      {
        'attachment_point':i2,
        'item_id':ud6852c11-a74e-309a-0462-50533f1ef9b3,
        'asset_id':uc69b29b1-8944-58ae-a7c5-2ca7b23e22fb
      },
      {
        'attachment_point':i10, 
        'item_id':uff852c22-a74e-309a-0462-50533f1ef900,
        'asset_id':u5868dd20-c25a-47bd-8b4c-dedc99ef9479
      }
    ]
  }
]

Guidelines

XML Encoding

When possible, prefer using us-ascii or or UTF-8 xml encoding.


Questions & Things To Do

Would Binary be more convenient as usigned char* buffer semantics?

Should Binary be convertable to/from String, and if so how?

  • as UTF8 encoded strings (making not like UUID<->String)
  • as Base64 or Base96 encoded (making like UUID<->String)

Conversions to std::string and LLUUID do not result in easy assignment to std::string, LLString or LLUUID due to non-unique conversion paths.