RFC1076

So, like other stack-based languages, the arguments and operators must be presented in postfix order, with an operator following its operands.

Here is a summary of all of the operators defined in the query language. Most of the operators can take several different sets of operands and behave differently based upon the operand types. Details and examples are given later.

BEGIN dict1 path BEGIN dict1 dict

                array path filter   BEGIN   array dict
         Move down in the data tree, establishing a context for
         future operations.

END dict END --

         Undo the most recent BEGIN.

GET dict GET dict

                    dict template   GET   dict
            array template filter   GET   array
         Retrieve data from the data tree.

GET-ATTRIBUTES

                             dict   GET-ATTRIBUTES   dict
                    dict template   GET-ATTRIBUTES   dict
            array template filter   GET-ATTRIBUTES   array
         Retrieve attribute information about data in the data tree.

GET-RANGE dict path start length GET-RANGE dict

         Retrieve a subrange of an OctetString.  Used for reading
         memory.

SET dict value SET dict

               array value filter   SET   array
         Change values in the data tree, possibly performing control
         functions.

CREATE array value CREATE dict

         Create new table entries.

DELETE array filter DELETE array

         Delete table entries.

These operators are defined so that it is impossible to generate an invalid query response. Since a response is supposed to be a snapshot of a portion (or portions) of the data tree, it is important that only data that is actually in the tree be put in the response. Two features of the language help guarantee this:

  - Data is put in the response directly from the tree (by
    GET-*).  Data does not go from the tree to the stack and
    then into the response.

  - Dictionaries on the stack are all derived from the initial,
    root dictionary.  The operations that manipulate
    dictionaries (BEGIN and END) also update the response with
    the new location in the tree.

Moving Around in the Data Tree

The initial point of reference in the data tree is the root. That is, operators name data starting at the root of the tree. It is useful to be able to move to some other dictionary in the tree and then name data from that point. The BEGIN operator moves down in the tree and END undoes the last unmatched BEGIN.

BEGIN is used for two purposes:

  - By moving to a dictionary closer to the data of interest,
    the name of the data can be shorter than if the full name
    (from the root) were given.

  - It is used to establish a context for filtered operations
    to operate in.  Filters are discussed in section 8.6.

BEGIN dict1 path BEGIN dict1 dict

         Follow <path> down the dictionary starting from <dict1>.
         Push the final dictionary named by <path> onto the stack.
         <path> must name a dictionary (not a leaf node).  At the
         same time, produce the beginning octets of an ASN.1 object
         corresponding to the new dictionary.  It is up to the
         implementation to choose between using the "indefinite
         length" representation or the "definite length" form and
         going back and filling the length in later.

END dict END --

         Pop <dict> off of the stack and terminate the open ASN.1
         object(s) started by the matching BEGIN.  Must be paired
         with a BEGIN.  If an END operation pops the root dictionary
         off of the stack, the query is terminated.

<path> must point to a regular dictionary. If any part of it refers to a non-existent node, if it points to a leaf node, or if it refers to a node inside an array-type dictionary, then it is in error, and the query is terminated immediately.

An additional form of BEGIN, which takes a filter argument, is described later.

Retrieving Data

The basic model that all of the data retrieval operations follow is that they take a template and fill in the leaf nodes of the template with the appropriate data values.

GET dict template GET dict

         Emit an ASN.1 object with the same "shape" as the given
         template, except with values filled in for each node.  The
         first ASN.1 tag of <template> should refer to an object in
         <dict>.  If a dictionary tag is supplied anywhere in
         <template>, the entire dictionary contents are emitted to
         the response.  Any items in the template that are not in
         <dictionary> (or its components) are represented as objects
         with a length of zero.

                             dict   GET   dict
         If there is no template, get all of the items in the
         dictionary.  This is equivalent to providing a template
         that lists all of the items in the dictionary.

An additional form of GET, which takes a filter argument, is described later.

Here is an example of using the BEGIN operator to move down the data tree to the TCP dictionary and then using the GET operator to retrieve 5 data values from the TCP Stats dictionary:

   IPTransport{ TCP } BEGIN
   Stats{ octetsIn, octetsOut, inputPkts, outputPkts, badtag } GET
   END

This might return:

   IPTransport{ TCP
       Stats{ octetsIn(13255), octetsOut(82323),
              inputPkts(9213), outputPkts(12425), badtag() }
   }

"badtag" is a tag value that is undefined. No value is returned for it, indicating that there is no data value associated with it.

Data Attributes

Although ASN.1 "self-describes" the structure and syntax of the data, it gives no information about what the data means. For example, by looking at the raw data, it is possible to tell that an item is of type [context 5] and is 4 octets long. That does not tell how to interpret the data (is this an integer, an IP address, or a 4- character string?) or what the data means (IP address of what?). Even if the data were "tagged", in ASN.1 parlance, that would only give the base type (e.g., IP-address or counter) and not the meaning.

Most of the time, this information will come from RFC-1024, which defines the ASN.1 tags and their precise meaning. When extensions have been made, it may not be possible to get documentation on the extensions. (Extensions are discussed in section 9.)

The GET-ATTRIBUTES operator is similar to the GET operator, but returns a set of attributes describing the data rather than the data itself. This information is intended to be sufficient to let a human understand the meaning of the data and to let a sophisticated application treat the data appropriately. Such an application could use the attribute information to format the data on a display and decide whether it is appropriate to subtract one sample from another.

Some of the attributes are textual descriptions to help a human understand the nature of the data and provide meaningful labels for it. Extensive descriptions of standard data are optional, since they are defined in RFC-1024. Complete descriptions of extensions must be available, even if they are documented in a user's manual. Network firefighters may not have a current manual handy when the network is broken.

The format of the attributes is not as simple as the format of the data itself. It isn't possible to use the data's tag, since that would look exactly like the data itself. The format is:

   Attributes ::= [APPLICATION 3] IMPLICIT SEQUENCE {
           tagASN1         [0] IMPLICIT INTEGER,

           valueFormat     [1] IMPLICIT INTEGER,
           longDesc        [2] IMPLICIT IA5String OPTIONAL,
           shortDesc       [3] IMPLICIT IA5String OPTIONAL,
           unitsDesc       [4] IMPLICIT IA5String OPTIONAL,
           precision       [5] IMPLICIT INTEGER OPTIONAL,
           properties      [6] IMPLICIT BITSTRING OPTIONAL,
           valueSet        [7] IMPLICIT SET OF valueDesc OPTIONAL
           }

The GET-ATTRIBUTES operator is similar to the GET operator. The major difference is that dictionaries named in the template do not elicit data for the entire subtree.

GET-ATTRIBUTES

                    dict template   GET-ATTRIBUTES   dict
         Emit a single ASN.1 Attributes object for each of the
         objects named in <template>.  For each of these, the
         tagASN1 field will be set to the corresponding tag from the
         template.  The rest of the fields are set as appropriate
         for the data object.  Any items in the template that are
         not in <dictionary> (or its components) elicit an
         Attributes object with a valueFormat of NULL, and no other
         descriptive information.

or

                             dict   GET-ATTRIBUTES   dict
         If there is no template, emit Attribute objects for all of
         the items in the dictionary.  This is equivalent to
         providing a template that lists all of the items in the
         dictionary.  This allows a complete list of a dictionary's
         contents to be obtained.

An additional form of GET-ATTRIBUTES, which takes a filter argument, is described later.

Here is an example of using the GET-ATTRIBUTES operator to request attributes for three objects in the System dictionary:

   System{ name, badtag, clock-msec } GET-ATTRIBUTES

"badtag" is some unknown tag. The result might be:

   System{
           Attributes{
                   tagASN1(name),
                   valueFormat(IA5String),
                   longDesc("The primary hostname."),

                   shortDesc("hostname")
           },
           Attributes{
                   tagASN1(badtag), valueFormat(NULL)
           }
           Attributes{
                   tagASN1(clock-msec),
                   valueFormat(Integer),
                   longDesc("milliseconds since boot"),
                   shortDesc("uptime"), unitsDesc("ms")
                   precision(4294967296),
                   properties(1)
           }

Note that in this example "name" and "clock-msec" are integer values for the ASN.1 tags for the two data items. "badtag" is an integer value that has no corresponding name in this context.

There will always be exactly as many Attributes items in the result as there are objects in the template. Attributes objects for items which do not exist in the entity will have a valueFormat of NULL and none of the optional elements will appear.

   [ A much cleaner method would be to store the attributes as
   sub-components of the data item of interest.  For example,
   requesting
       System{ clock-msec }  GET
   would normally just get the value of the data.  Asking for an
   additional layer down the tree would now get its attributes:
       System{ clock-msec{ shortDesc, unitsDesc }  GET
   would get the named attributes.  (The attributes would be
   named with application-specific tags.)  Unfortunately, ASN.1
   doesn't provide a notation to describe this type of
   organization.  So, we're stuck with the GET-ATTRIBUTES
   operator.  However, if a cleaner organization were possible,
   this decision would have been made differently. ]

Examining Memory

Even with the ability to symbolically access all of this information in an entity, there will still be times when it is necessary to get to very low levels and examine memory, as in remote debugging operations. The building blocks outlined so far can easily be extended to allow memory to be examined.

Memory is modeled as an ordinary object in the data tree, with an ASN.1 representation of OctetString. Because of the variety of addressing architectures in existence, the conversion from the

internal memory model to OctetString is very machine-dependent. The only simple case is for byte-addressed machines with 8 bits per byte.

Each address space in an entity is represented by one "memory" data item. In a one-address-space situation, this dictionary will probably be in "System" dictionary. If each process has its own address space, then one "memory" item might exist for each process. Again, this is very machine-dependent.

Although the GET-RANGE operator is provided primarily for the purpose of retrieving the contents of memory, it can be used on any object whose base type is OctetString.

GET-RANGE dict path start length GET-RANGE dict

         Get <length> elements of the OctetString, starting at
         <start>.  <start> and <length> are both ASN.1 INTEGER type.
         <path>, starting from <dict>, must specify a node
         representing memory, or some other OctetString.

The returned data may not be <length> octets long, since it may take more than one octet to represent one memory location.

Memory items in the data tree are special in that they will not automatically be returned when the entire contents of a dictionary are requested. e.g., If memory is part of the "System" dictionary, then the query

   System GET

will emit the entire contents of the System dictionary, but not the memory item.

Control Operations: Modifying the Data Tree

All of the operators defined so far only allow data in an entity to be retrieved. By replacing the template argument used in the GET operators with a value, data in the entity can be changed. Very few items in the data tree can be changed; those that can are noted in RFC-1024.

Values in the data tree can modified in order to change configuration parameters, patch routing tables, etc. Control functions, such as bringing an interface "down" or "up", do not usually map directly to changing a value. In such cases, an item in the tree can be defined to have arbitrary side-effects when a value is assigned to it. Control operations then consist of "setting" this item to an appropriate command code. Reading the value of such an item might return the current status. Again, details of such data tree items are given in RFC-1024.

This "virtual command-and-status register" model is very powerful, and can be extended by an implementation to provide whatever controls are needed. It has the advantage that the control function is associated with the controlled object in the data tree. In addition, no additional language features are required to support control functions, and the same operations used to locate data for retrieval are used to describe what is being controlled.

For all of the control and data modification operations, the fill- in-the-blank model used for data retrieval is extended: the response to an operation is the affected part of the data tree, after the operation has been executed. Therefore, for normal execution, SET and CREATE will return the object given as an argument, and DELETE will return nothing (because the affected portion was deleted).

SET dict value SET dict

         Set the value(s) of data in the entity to the value(s)
         given in <value>.  The result will be the value of the data
         after the SET.  Attempting to set a non-settable item will
         not produce an error, but will yield a result in the reply
         different from what was sent.

CREATE array value CREATE dict

         Insert a new entry into <array>.  Depending upon the
         context, there may be severe restrictions about what
         constitutes a valid <value>.  The result will be the actual
         item added to the <array>.  Note that only one item can be
         added per CREATE operation.

DELETE array filter DELETE array

         Delete the entry(s) in <array> that match <filter>.
         Filters are described later in this document.  Normally, no
         data items will be produced in the response, but if any of
         the items that matched the filter could not be deleted,
         they will be returned in the response.

An additional form of SET, which takes a filter argument, is described later.

Here is an example of attempting to use SET to change the number of interfaces in an entity:

   System{ interfaces(5) } SET

Since that is not a settable parameter, the result would be:

   System{ interfaces(2) }

giving the old value.

Here is an example of how CREATE would be used to add a routing table entry for net for 128.89.0.0.

   IPRouting BEGIN                   -- get dictionary
   Entries{ DestAddr(128.89.0.0), ... }    -- entry to insert
   CREATE
   END                                 -- finished with dict

The result would be what was added:

   IPRouting{ Entries{ DestAddr(128.89.0.0), ... } }

The results in the response of these operators is consistent of the global model of the response: it contains a subset of the data in the tree immediately after the query is executed.

Note that CREATE and DELETE only operate on arrays, and then only on arrays that are specifically intended for it. For example, it is quite reasonable to add and remove entries from routing tables or ARP tables, both of which are arrays. However, it doesn't make sense to add or remove entries in the "Interfaces" dictionary, since the contents of that array is dictated by the hardware. For each array in the data tree, RFC-1024 indicates whether CREATE and DELETE are valid.

CREATE and DELETE are always invalid in non-array contexts. If DELETE were allowed on monitored data, then the deleted data would become unmonitorable to the entire world. Conversely, if it were possible to CREATE arbitrary dictionary entries, there would be no way to give such entries any meaning. Even with the data in place, there is nothing that would couple the data to the operation of the monitored entity. [Creation and deletion would also add considerable complication to an implementation, because without them, all of the data structures that represent the data tree are essentially static, with the exception of dynamic tables such as the ones mentioned, which already have mechanisms in place for adding and removing entries.]

Associative Data Access: Filters

One problem that has not been dealt with was alluded to earlier: When dealing with array data, how do you specify one or more entries based upon some value in the array entries? Consider the situation where there are several interfaces. The data might be organized as:

   Interfaces {                            -- one per interface
           InterfaceData { address, mtu, netMask, ARP{...}, ... }
           InterfaceData { address, mtu, netMask, ARP{...}, ... }
                           :
           }

If you only want information about one interface (perhaps because

there is an enormous amount of data about each), then you have to have some way to name it. One possibility would be to just number the interfaces and refer to the desired interface as

   InterfaceData(3)

for the third one.

But this is not sufficient, because interface numbers may change over time, perhaps from one reboot to the next. It is even worse when dealing with arrays with many elements, such as routing tables, TCP connections, etc. Large, changing arrays are probably the more common case, in fact. Because of the lack of utility of indexing in this context, there is no general mechanism provided in the language for indexing.

A better scheme is to select objects based upon some value contained in them, such as the IP address. The query language uses filters to select specific table entries that an operator will operate on. The operators BEGIN, GET, GET-ATTRIBUTES, SET, and DELETE can take a filter argument that restricts their operation to entries that match the filter.

A filter is a boolean expression that is executed for each element in an array. If an array entry "matches" the filter (i.e., if the filter produces a "true" result), then it is used by the operation. A filter expression is very restricted: it can only compare data contained in the array element and the comparisons are only against constants. Comparisons may be connected by AND, OR and NOT operators.

The ASN.1 definition of a filter is:

   Filter          ::= [APPLICATION 2] CHOICE {
                           present         [0] DataPath,
                           equal           [1] DataValue,
                           greaterOrEqual  [2] DataValue,
                           lessOrEqual     [3] DataValue,
                           and             [4] SEQUENCE OF Filter,
                           or              [5] SEQUENCE OF Filter,
                           not             [6] Filter
                           }

   DataPath        ::= ANY                 -- Path with no value

   DataValue       ::= ANY                 -- Single data value

This definition is similar to the filters used in the ISO monitoring protocol (CMIP) and was derived from that specification.

"DataPath" is the name of a single data item; "DataValue" is the value of a single data item. The three comparisons are all of the form "data OP constant", where "data" is the value from the tree, "constant" is the value from the filter expression, and "OP" is one of equal, greater-than-or-equal, or less-than-or-equal. The last operation, "present", tests to see if the named item exists in the data tree. By its nature, it requires no value, so only a path needs to be given.

Here is an example of a filter that matches an Interface whose IP address is 10.1.0.1:

   Filter{ equal{ address(10.0.0.51) } }

Note that the name of the data to be compared is relative to the "InterfaceData" dictionary.

Each operator, when given a filter argument, takes an array (dictionary containing only one type of item) as its first argument. In the current example, this would be "Interfaces". The items in it are all of type "InterfaceData". This tag is referred to as the "iteration tag".

Before a filtered operation is used, BEGIN must be used to put the array (dictionary) on top of the stack, to establish it as the context that the filter iterates over. The general operation of a filtered operation is then:

     1. Iterate over the items in the array.

     2. For each element in the array, execute the filter.

     3. If the filter succeeds, do the requested operation
        (GET/SET/etc.) on the matched element, using the
        template/value/path as input to the operation.  At this
        point, the execution of the operation is the same as in
        the non-filtered case.

This is a model of operation; actual implementations may take advantage of whatever lookup techniques are available for the particular table (array) involved.

Therefore, there are three inputs to a filtered operation:

     1. The "current dictionary" on the stack.  This is the
        array-type dictionary to be searched, set by an earlier
        BEGIN.

     2. A filter, to test each item in the array.  Each path or
        value mentioned in the filter must be named in the context

        of an item in the array, as if it was the current
        dictionary.  For example, in the case where a filtered
        operation iterates over the set of "InterfaceData" items
        in the "Interfaces" array, each value or path in the
        filter should name an item in the "InterfaceData"
        dictionary, such as "address".

     3. A template, path, or value associated with the operation
        to be performed.  The leading ASN.1 tag in this must match
        the iteration tag.  In the current example where the
        filter is searching the "Interfaces" dictionary, the first
        tag in the template/tag/value must be "InterfaceData".

The operators which take filters as arguments are:

BEGIN array path filter BEGIN array dict

         Find a dictionary in <array> that matches <filter>.  Use
         that as the starting point for <path> and push the
         dictionary corresponding to <path> onto the stack.  If more
         than one dictionary matches <filter>, then any of the
         matches may be used.  This specification does not state how
         the choice is made.  At least one dictionary must match; it
         is an error if there are no matches.  (Perhaps it should be
         an error for there to be multiple matches; actual
         experience is needed to decide.)

GET array template filter GET array

         For each item in <array> that matches <filter>, fill in the
         template with values from the data tree and emit the
         result.  The first tag of <template> must be equal to the
         iteration tag.  Selected parts of matched items are emitted
         based upon <template>, just as in a non-filtered GET
         operation.

GET-ATTRIBUTES

            array template filter   GET-ATTRIBUTES   array
         Same as GET, except emit attributes rather than data
         values.

SET array value filter SET array

         Same as GET, except set the values in <value> rather than
         retrieving values.  Several values in the data tree will be
         changed if the filter matches more than one item in the
         array.

DELETE array filter DELETE array

         Delete the entry(s) in <array> that match <filter>.

Notes about filter execution:

  - Expressions are executed by inorder tree traversal.

  - Since the filter operations are all GETs and comparisons,
    there are no side-effects to filter execution, so an
    implementation is free to execute only as much of the
    filter as required to produce a result (e.g., don't execute
    the rest of an AND if the first comparison turns out to be
    false).

  - It is not an error for a filter to test a data item that
    isn't in the data tree.  In this situation, the comparison
    just fails (is false).  This means that filters don't need
    to test for the existence of optional data before
    attempting to compare it.

Here is an example of how filtering would be used to obtain the input and output packet counts for the interface with IP address 10.0.0.51.

   Interfaces BEGIN                      -- dictionary
   InterfaceData{ pktsIn, pktsOut }      -- template
   Filter{ equal{ address(10.0.0.51) } }
   GET
   END                                   -- finished with dict

The returned value would be something like:

   Interfaces{                             -- BEGIN
     InterfaceData{ pktsIn(1345134), pktsOut(1023729) }
                                           -- GET
   }                                       -- END

The annotations indicate which part of the response is generated by the different operators in the query.

Here is an example of accessing a table contained within some other table. Suppose we want to get at the ARP table for the interface with IP address 36.8.0.1 and retrieve the entire ARP entry for the host with IP address 36.8.0.23. In order to retrieve a single entry in the ARP table (using a filtered GET), a BEGIN must be used to get down to the ARP table. Since the ARP table is contained within the Interfaces dictionary (an array), a filtered BEGIN must be used.

   Interfaces BEGIN                        -- dictionary
   InterfaceData{ ARP }                    -- path
   Filter{ equal{ address(36.8.0.1) } }    -- filter
   BEGIN                                   -- filtered BEGIN

   -- Now in ARP table for 38.0.0.1; get entry for 38.8.0.23.
   addrMap                                 -- whole entry
   Filter{ equal{ ipAddr(36.8.0.23) } }    -- filter
   GET                                     -- filtered GET
   END
   END

The result would be:

   Interfaces{                             -- first BEGIN
     InterfaceData{ ARP{                   -- second BEGIN
       addrMap{ ipAddr(36.8.0.23), physAddr(..) } -- from GET
     } }                                   -- first END
   }                                       -- second END

Note which parts of the output are generated by different parts of the query.

Here is an example of how the SET operator would be used to shut down the interface with ip-address 10.0.0.51 by changing its status to "down".

   Interfaces BEGIN                    -- get dictionary
   Interface{ Status(down) }           -- value to set
   Filter{ equal{ IP-addr(10.0.0.51) } }
   SET
   END

If the SET is successful, the result would be:

   Interfaces{                             -- BEGIN
       Interface{ Status(down) }           -- from SET
   }                                       -- END

Terminating a Query

A query is implicitly terminated when there are no more ASN.1 objects to be processed by the interpreter. For a perfectly-formed query, the interpreter would be back in the state it was when it started: the stack would have only the root dictionary on it, and all of the ASN.1 objects in the result would be terminated.

If there are still "open" ASN.1 objects in the result (caused by leaving ENDs off of the query), then these are closed, as if a sufficient number of ENDs were provided. This condition would be indicated by the existence of dictionaries other than the root dictionary on the stack.

If an extra END is received that would pop the root dictionary off of the stack, the query is terminated immediately. No error is generated.

EXTENDING THE SET OF VALUES

There are two ways to extend the set of values understood by the query language. The first is to register the data and its meaning and get an ASN.1 tag assigned for it. This is the preferred method because it makes that data specification available for everyone to use.

The second method is to use the VendorSpecific application type to "wrap" the vendor-specific data. Wherever an implementation defines data that is not in RFC-1024, the "VendorSpecific" tag should be used to label a dictionary containing the vendor-specific data. For example, if a vendor had some data associated with interfaces that was too strange to get standard numbers assigned for, they could, instead represent the data like this:

      interfaces {
              interface {
                      in-pkts, out-pkts, ...
                      VendorSpecific { ephemeris, declination }
                      }
              }

In this case, ephemeris and declination correspond to two context- dependent tags assigned by the vendor for their non-standard data.

If the vendor-specific method is chosen, the private data MUST have descriptions available through the GET-ATTRIBUTES operator. Even with this descriptive ability, the preferred method is to get standard numbers assigned if possible.

10. AUTHORIZATION

This specification does not state what type of authorization system is used, if any. Different systems may have needs for different mechanisms (authorization levels, capability sets, etc.), and some systems may not care about authorization at all. The only effect that an authorization system has on a query is to restrict what data items in the tree may be retrieved or modified.

Therefore, there are no explicit query language features that deal with protection. Instead, protection mechanisms are implicit and may make some of the data invisible (for GET) or non-writable (for SET):

  - Each query runs with some level of authorization or set of
    capabilities, determined by its environment (HEMS and the
    HEMP header).

  - Associated with each data item in the data tree is some
    sort of test to determine if a query's authorization should
    grant it access to the item.

Authorization tests are only applied to query language operations that retrieve information (GET, GET-ATTRIBUTES, and GET-RANGE) or modify it (SET, CREATE, DELETE). An authorization system must not affect the operation of BEGIN and END. In particular, the authorization must not hide entire dictionaries, because that would make a BEGIN on such a dictionary fail, terminating the entire query.

11. ERRORS

If some particular information is requested but is not available, it will be returned as "no-value" by giving the ASN.1 length as 0.

When there is any other kind of error, such as having improper arguments on the top of the stack or trying to execute BEGIN when the path doesn't refer to a dictionary, an ERROR object is emitted.

The contents of this object identify the exact nature of the error:

      Error ::= [APPLICATION 0] IMPLICIT SEQUENCE {
              errorCode       INTEGER,
              errorInstance   INTEGER,
              errorOffset     INTEGER
              errorDescription IA5String,
              errorOp         INTEGER,
              }

errorCode identifies what the error was, and errorInstance is an implementation-dependent code that gives a more precise indication of where the error occured. errorOffset is the location within the query where the error occurred. If an operation was being executed, errorOp contains its operation code, otherwise zero. errorDescription is a text string that can be printed that gives some description of the error. It will at least describe the errorCode, but may also give details implied by errorInstance. Detailed definitions of all of the fields are given in appendix I.2.

Since there may be several unterminated ASN.1 objects in progress at the time the error occurs, each one must be terminated. Each unterminated object will be closed with a copy of the ERROR object. Depending upon the type of length encoding used for this object, this

will involve filling the value for the length (definite length form) or emitting two zero octets (indefinite length form). After all objects are terminated, a final copy of the ERROR object will be emitted. This structure guarantees that the error will be noticed at every level of interpretation on the receiving end.

In summary, if there was an error before any ASN.1 objects were generated, then the result would simply be:

   error{...}

If a couple of ASN.1 objects were unterminated when the error occurred, the result might look like:

   interfaces{
        interface { name(...) type(...) error{...} }
        error{...}
        }
   error{...}

It would be possible to define a "WARNING" object that has a similar (or same) format as ERROR, but that would be used to annotate responses when a non-fatal "error" occurs, such as attempting to SET/CREATE/DELETE and the operation is denied. This would be an additional complication, and we left it out in the interests of simplicity.

I. ASN.1 DESCRIPTIONS OF QUERY LANGUAGE COMPONENTS

A query consists of a sequence of ASN.1 objects, as follows:

   Query := IMPLICIT SEQUENCE of QueryElement;

   QueryElement ::= CHOICE {
           Operation,
           Filter,
           Template,
           Path,
           InputValue
           }

Operation and Filter are defined below. The others are:

   Template        ::= any
   Path            ::= any
   InputValue      ::= any

These three are all similar, but have different restrictions on their structure:

Template Specifies a portion of the tree, naming one or more

               values, but not containing any values.

Path Specifies a single path from one point in the tree to

               another, naming exactly one value, but not containing
               a value.

InputValue Gives a value to be used by a query language

               operator.

A query response consists of a sequence of ASN.1 objects, as follows:

   Response := IMPLICIT SEQUENCE of ResponseElement;

   ResponseElement ::= CHOICE {
           ResultValue,
           Error
           }

Error is defined below. The others are:

   ResultValue     ::= any

ResultValue is similar to Template, above:

ResultValue Specifies a portion of the tree, naming and

               containing one or more values.

The distinctions between these are elaborated in section 6.

I.1 Operation Codes

Operation codes are all encoded in a single application-specific type, whose value determines the operation to be performed. The definition is:

   Operation ::= [APPLICATION 1] IMPLICIT INTEGER {
           reserved(0),
           begin(1),
           end(2),
           get(3),
           get-attributes(4),
           get-range(5),
           set(6),

           create(7),
           delete(8)
           }

I.2 Error Returns

An Error object is returned within a reply when an error is encountered during the processing of a query. Note that the definition this object is similar to that of the HEMP protocol error structure. The error codes have been selected to keep the code spaces distinct between the two. This is intended to ease the processing of error messages. See section 11 for more information.

   Error ::= [APPLICATION 0] IMPLICIT SEQUENCE {
           errorCode       INTEGER,
           errorInstance   INTEGER,
           errorOffset     INTEGER
           errorDescription IA5String,
           errorOp         INTEGER,
           }

The fields are defined as follows:

errorCode Identifies the general cause of the error.

errorInstance An implementation-dependent code that gives a more

               precise indication of where the error occured in the
               query processor.  This is most useful when internal
               errors are reported.

errorOffset The location within the query where the error was

               detected.  The first octet of the query is numbered
               zero.

errorOp If an operation was being executed, this contains its

               operation code, otherwise zero.

errorDescription

               A text string that can be printed that gives some
               description of the error.  It will at least describe
               the errorCode, but may also give details implied by
               errorInstance.

Some errors are associated with the execution of specific operations, and others with the overall operation of the query interpreter. The errorCodes are split into two groups.

The first group deals with overall interpreter operation. Except for

"unknown operation", these do not set errorOp.

100 Other error.

               Any error not listed below.

101 Format error.

               An error has been detected in the format of the input
               stream, preventing further interpretation of the
               query.

102 System error.

               The query processor has failed in some way due to an
               internal error.

103 Stack overflow.

               Too many items were pushed on the stack.

104 Unknown operation.

               The operation code is invalid.  errorOp is set.

The second group is errors that are associated with the execution of particular operations. errorOp will always be set for these.

200 Other operation error.

               Any error, associated with an operation, not listed
               below.

201 Stack underflow.

               An operation expected to see some number of operands
               on the stack, and there were fewer items on the
               stack.

202 Operand error.

               An operation expected to see certain operand types on
               the stack, and something else was there.

203 Invalid path for BEGIN.

               A path given for BEGIN was invalid, because some
               element in the path didn't exist.

204 Non-dictionary for BEGIN.

               A path given for BEGIN was invalid, because the given
               node was a leaf node, not a dictionary.

205 BEGIN on array element.

               The path specified an array element.  The path must
               point at a single, unique, node.  A filtered BEGIN
               should have been used.

206 Empty filter for BEGIN.

               The filter for a BEGIN didn't match any array
               element.

207 Filtered operation on non-array.

               A filtered operation was attempted on a regular
               dictionary.  Filters can only be used on arrays.

208 Index out of bounds.

               The starting address or length for a GET-RANGE
               operation went outside the bounds for the given
               object.

209 Bad object for GET-RANGE.

               GET-RANGE can only be applied to objects whose base
               type is OctetString.

This list is probably not quite complete, and would need to be extended, based upon implementation experience.

I.3 Filters

Many of the operations can take a filter argument to select among elements in an array. They are discussed in section 8.6.

    Filter          ::= [APPLICATION 2] CHOICE {
                           present         [0] DataPath,
                           equal           [1] DataValue,
                           greaterOrEqual  [2] DataValue,
                           lessOrEqual     [3] DataValue,
                           and             [4] SEQUENCE OF Filter,
                           or              [5] SEQUENCE OF Filter,
                           not             [6] Filter
                           }

   DataPath        ::= ANY                 -- Path with no value

   DataValue       ::= ANY                 -- Single data value

A filter is executed by inorder traversal of its ASN.1 structure.

The basic filter operations are:

present tests for the existence of a particular data item in

               the data tree

equal tests to see if the named data item is equal to the

               given value.

greaterOrEqual tests to see if the named data item is greater than

               or equal to the given value.

lessOrEqual tests to see if the named data item is less than or

               equal to the given value.

These may be combined with "and", "or", and "not" operators to form arbitrary boolean expressions. The "and" and "or" operators will take any number of terms. Terms are only evaluated up to the point where the outcome of the expression is determined (i.e., an "and" term's value is false or an "or" term's value is true).

I.4 Attributes

One or more Attributes structure is returned by the GET-ATTRIBUTES operator. This structure provides descriptive information about items in the data tree. See the discussion in section 8.3.

   Attributes ::= [APPLICATION 3] IMPLICIT SEQUENCE {
           tagASN1         [0] IMPLICIT INTEGER,
           valueFormat     [1] IMPLICIT INTEGER,
           longDesc        [2] IMPLICIT IA5String OPTIONAL,
           shortDesc       [3] IMPLICIT IA5String OPTIONAL,
           unitsDesc       [4] IMPLICIT IA5String OPTIONAL,
           precision       [5] IMPLICIT INTEGER OPTIONAL,
           properties      [6] IMPLICIT BITSTRING OPTIONAL,
           valueSet        [7] IMPLICIT SET OF valueDesc OPTIONAL
           }
   valueDesc ::= IMPLICIT SEQUENCE {
           value           [0] ANY,        -- Single data value
           desc            [1] IA5String
           }

The meanings of the various attributes are given below.

tagASN1 The ASN.1 tag for this object. This attribute is

               required.

valueFormat The underlying ASN.1 type of the object (e.g.,

               SEQUENCE or OCTETSTRING or Counter).  This is not
               just the tag number, but the entire tag, as it would
               appear in an ASN.1 object.  As such, it includes the
               class, which should be either UNIVERSAL or
               APPLICATION.  Applications receiving this should

               ignore the constructor bit.  This attribute is
               required.

longDesc A potentially lengthy text description which fully

               defines the object.  This attribute is optional for
               objects defined in this memo and required for
               entity-specific objects.

shortDesc A short mnemonic string of less than 15 characters,

               suitable for labeling the value on a display.  This
               attribute is optional.

unitsDesc A short string used for integer values to indicate

               the units in which the value is measured (e.g., "ms",
               "sec", "pkts", etc.).  This attribute is optional.

precision For Counter objects, the value at which the Counter

               will roll-over.  Required for all Counter objects.

properties A bitstring of boolean properties of the object. If

               the bit is on, it has the given property.  This
               attribute is optional.  The bits currently defined
               are:

               0   If true, the difference between two values of
                   this object is significant.  For example, the
                   changes of a packet count is always significant,
                   it always conveys information.  In this case, the
                   0 bit would be set.  On the other hand, the
                   difference between two readings of a queue length
                   may be meaningless.

               1   If true, the value may be modified with SET,
                   CREATE, and DELETE.  Applicability of CREATE and
                   DELETE depends upon whether the object is in an
                   array.

               2   If true, the object is a dictionary, and a BEGIN
                   may be used on it.  If false, the object is leaf
                   node in the data tree.

               3   If true, the object is an array-type dictionary,
                   and filters may be used to traverse it.  (Bit 2
                   will be true also.)

valueSet For data that is defined as an ASN.1 CHOICE type (an

               enumerated type), this gives descriptions for each of
               the possible values that the data object may assume.

               Each valueDesc is a <value,description> pair.  This
               information is especially important for control
               items, which are very likely to appear in
               VendorSpecific dictionaries, exactly the situation
               where descriptive information is needed.

I.5 VendorSpecific

See the discussion in section 9.

   VendorSpecific          ::= [APPLICATION 4] IMPLICIT SET
                                   of ANY

II. IMPLEMENTATION HINTS

Although it is not normally in the spirit of RFCs to define an implementation, the authors feel that some suggestions will be useful to implementors of the query language. This list is not meant to be complete, but merely to give some hints about how the authors imagine that the query processor might be implemented efficiently.

  - It should be understood that the stack is of very limited
    depth.  Because of the nature of the query language, it can
    get only about 4 entries (for arguments) plus the depth of
    the tree (up to one BEGIN per level in the tree).  This
    comes out to about a dozen entries in the stack, a modest
    requirement.

  - The stack is an abstraction -- it should be implemented
    with pointers, not by copying dictionaries, etc.

  - An object-oriented approach should make implementation
    fairly easy.  Changes to the "shape" if the data items
    (which will certainly occur, early on) will also be easier
    to make.

  - Only a few "messages" need to be understood by objects.  By
    having pointers to action routines for each basic operation
    (GET,SET,...) associated with each node in the tree, common
    routines (e.g., emit a long integer located at address X)
    can be shared, and special routines (e.g., set the interface
    state for interface X) can be implemented in a common
    framework.  Higher levels need know nothing about what data
    is being dealt with.

  - Most interesting objects are dictionaries, each of which
    can be implemented using pointers to the data and procedure
    "hooks" to perform specific operations such as GET, SET,

    filtering, etc.

  - The hardest part is actually extracting the data from
    existing TCP/IP implementations that weren't designed with
    detailed monitoring in mind.  Query processors interfacing
    to a UNIX kernel will have to make many system calls in
    order to extract some of the more intricate structures,
    such as routing tables.  This should be less of a problem
    if a system is designed with easy monitoring as a goal.

A Skeletal Implementation

This section gives a rather detailed example of the core of a query processor. This code has not been tested, and is intended only to give implementors ideas about how to tackle some aspects of query processor implementation with finesse, rather than brute force.

The suggested architecture is for each dictionary to have a "traverse" routine associated with it, which is called when any sort of operation has to be done on that dictionary. Most nodes will share the same traversal routine, but array dictionaries will usually have routines that know about whatever special lookup mechanisms are required.

Non-dictionary nodes would have two routines, "action", and "compare", which implement query language operations and filter comparisons, respectively. Most nodes would share these routines.

For example, there should be one "action" routine that does query language operations on 32-bit integers, and another that works on 16-bit integers, etc.

Any traversal procedure would take arguments like:

   traverse(node, mask, op, filter)
           Treenode        node;   /* generic node-in-tree */
           ASN             mask;   /* internal ASN.1 form */
           enum opset      op;     /* what to do */
           Filter          filter; /* zero if no filter */

   enum opset { begin, get, set, create, delete, geta,
                   c_le, c_ge, c_eq, c_exist };

The traversal procedure is called whenever anything must be done within a dictionary. The arguments are:

node the current dictionary.

mask is either the template, path, or value, depending

               upon the operation being performed.  The top-level
               identifier of this object will be looked up in the
               context of <node>.

op is the operation to be performed, either one of the

               basic operations, or a filter operation.

filter is the filter to be applied, or zero if none. There

               will be no filter when <op> is a filter-comparison
               operation.

The general idea is that the traversal proc associated with a node has all of the knowledge about how to get around in this subtree encoded within it. Hopefully, this will be the only place this knowledge is coded. Here is a skeleton of the "standard" traversal proc, written mostly in C.

When the query processor needs to execute a "GET" operation, it would just call:

   traverse(current, template, GET, 0)

Notes about this example:

  - This traversal routine handles either query language
    operations (GET, SET, etc.) or low-level filter operations.
    Separate routines could be defined for the two classes of
    operations, but they do much of the same work.

  - Dictionary nodes have a <traversal> proc defined.

  - Leaf nodes have an <action> proc, which implement GET, SET,
    GET-ATTRIBUTES, CREATE, and DELETE, and a <compare> proc,
    which performs low-level filter comparisons.

  - In the generic routine, the filter argument is unused,
    because the generic routine isn't used for array
    dictionaries, and only array dictionaries use filters.

  - An ASN type contains the top level tag and a list of
    sub-components.

  - size(mask) takes an ASN.1 object and tells how many
    sub-items are in it.  Zero means that this is a simple
    object.

  - lookup(node, tag) looks up a tag in the given (tree)node,
    returning a pointer to the node.  If the tag doesn't exist

    in that node, a pointer to a special node "NullItem" is
    returned.  NullItem looks like a leaf node and has procs
    that perform the correct action for non-existent data.

  - This example does not do proper error handling, or ASN.1
    generation, both of which would require additional code in
    this routine.

   /*
    *  For op = GET/SET/etc, return:
    *              true on error, otherwise false.
    *  When op is a filter operation, return:
    *              the result of the comparison.
    */
   int std_traverse(node, mask, op, filter)
       Treenode    node;   /* current node */
       ASN         mask;   /* internal ASN.1 form */
       enum opset  op;     /* what to do */
       Filter      filter; /* unused in this routine */
   {
       ASN         item;
       Treenode    target;
       boolean     rv = false;
       extern Treenode NullItem;

       if (filter != null) {
           error(...);
           return true;
       }

       target = lookup(node, mask.tag);

       /*  We are at the leaf of the template/path/value.  */
       if (size(mask) == 0)
           switch (op)
           {
           case BEGIN:
               /*  non-existent node, or leaf node  */
               if (target == NullItem || target.traverse == 0) {
                   error(...);
                   return true;
                   }
               else {
                   begin(node, mask.tag);
                   return false;
                   }

           case GET:       case SET:       case GETA:

           case GETR:      case CREATE:    case DELETE:
               /*  A leaf in the mask specifies entire directory.
                   For GET, traverse the entire subtree.  */
               if (target.traverse)
                   if (op == GET) {
                       foreach subnode in target
                           /*  Need to test to not GET memory.  */
                           rv |= (*target.traverse)
                                   (target, subnode.tag, op, 0);
                       return rv;
                   }
                   else if (op == SET)     /*  no-op  */
                       return false;
                   else if (op != GETA) {
                       error(...);
                       return true;
                   }
               /*  We're at a leaf in both the mask and the tree.
                   Just execute the operation.
               */
               else {
                   if (op == BEGIN) {  /*  Can't begin on leaf  */
                       error(...);
                       return true;
                   else
                       return (*target.action)(target, mask, op);
                   }
               }  /* else */

           default:        /*  Comparison ops.  */
               return (*target.compare)(target, mask, op);
           }  /* switch */

       /*  We only get here if mask has structure.  */

       /*  can't have multiple targets for BEGIN  */
       if (op == BEGIN && size(mask) != 1) {
           error(...);
           return true;
       }
       /*  or for a single filter operation.  */
       if (op is comparison && size(mask) != 1) {
           error(...);
           return false;
       }
       /*  Iterate over the components in mask  */
       foreach item in mask
       {

           if (target.traverse)    /*  traverse subtree.  */
               rv |= (*component.traverse)(component, item, op, 0);
           else                    /*  leaf node, at last.  */
               if (op is comparison)
                   return (*target.compare)(target, mask, op);
               else
                   return (*target.action)(target, mask, op);
       } /* foreach */

       return rv;
   }  /* std_traverse */

Here is a bare skeleton of an array-type dictionary's traversal proc.

   int array_traverse(node, mask, op, filter)
       Treenode    node;   /* current node */
       ASN         mask;   /* internal ASN.1 form */
       enum opset  op;     /* what to do */
       Filter      filter; /* unused in this routine */
   {
       Treenode    target;
       boolean     rv = false;
       extern Treenode NullItem;

       /*  Didn't find that key.  */
       if (mask.tag != this array's iteration tag)
           return false;

       if (op == BEGIN && filter == null) {
           error(...);
           return 1;
       }

       /*  The implementation of this loop is the major trick!  */
       /*  Needs to stop after first filter success on BEGIN.  */
       foreach target in node {
           if (filter == null ||           /*  if no filter, or */
               ExecFilter(target, filter)) /* if it succeeds  */
               rv |= (target.traverse*)(target, mask, op, 0);
       }
   }  /* array_traverse */

Object-oriented programming languages, such as C++, Modula, and Ada, are well suited to this style of implementation. There should be no particular difficulty with using a conventional language such as C or Pascal, however.

III. OBTAINING A COPY OF THE ASN.1 SPECIFICATION

Copies of ISO Standard ASN.1 (Abstract Syntax Notation 1) are available from the following source. It comes in two parts; both are needed:

   IS 8824 -- Specification (meaning, notation)
   IS 8825 -- Encoding Rules (representation)

They are available from:

   Omnicom Inc.
   115 Park St, S.E.          (new address as of March, 1987)
   Vienna, VA  22180
   (703) 281-1135