Rfc | 1228 |
Title | SNMP-DPI: Simple Network Management Protocol Distributed Program
Interface |
Author | G. Carpenter, B. Wijnen |
Date | May 1991 |
Format: | TXT, HTML |
Obsoleted by | RFC1592 |
Status: | EXPERIMENTAL |
|
Network Working Group G. Carpenter
Request for Comments: 1228 B. Wijnen
T.J. Watson Research Center, IBM Corp.
May 1991
SNMP-DPI
Simple Network Management Protocol
Distributed Program Interface
Status of this Memo
This RFC describes a protocol that International Business Machines
Corporation (IBM) has been implementing in most of its SNMP agents to
allow dynamic extension of supported MIBs. This is an Experimental
Protocol for the Internet community. Discussion and suggestions for
improvement are requested. Please refer to the current edition of
the "IAB Official Protocol Standards" for the standardization state
and status of this protocol. Distribution of this memo is unlimited.
ABSTRACT
The Simple Network Management Protocol (SNMP) [1] Distributed Program
Interface (DPI) is an extension to SNMP agents that permits end-users
to dynamically add, delete or replace management variables in the
local Management Information Base without requiring recompilation of
the SNMP agent. This is achieved by writing a so-called sub-agent
that communicates with the agent via the SNMP-DPI.
For the author of a sub-agent, the SNMP-DPI eliminates the need to
know the details of ASN.1 [2] or SNMP PDU (Protocol Data Unit)
encoding/decoding [1, 3].
This protocol has been in use within IBM since 1989 and is included
in the SNMP agents for VM, MVS and OS/2.
Potentially useful sample sub-agent code and implementation examples
are available for anonymous FTP from the University of Toronto.
MOTIVATION
The Simple Network Management Protocol [1] defines a protocol that
permits operations on a collection of variables. This set of
variables is called the Management Information Base (MIB) and a core
set of variables has previously been defined [4, 5]; however, the
design of the MIB makes provision for extension of this core set.
Thus, an enterprise or individual can define variables of their own
which represent information of use to them. An example of a
potentially interesting variable which is not in the core MIB would
be CPU utilization (percent busy). Unfortunately, conventional SNMP
agent implementations provide no means for an end-user to make
available new variables.
The SNMP DPI addresses this issue by providing a light-weight
mechanism by which a process can register the existence of a MIB
variable with the SNMP agent. When requests for the variable are
received by the SNMP agent, it will pass the query on to the process
acting as a sub-agent. This sub-agent then returns an appropriate
answer to the SNMP agent. The SNMP agent eventually packages an SNMP
response packet and sends the answer back to the remote network
management station that initiated the request.
None of the remote network management stations have any knowledge
that the SNMP agent calls on other processes to obtain an answer. As
far as they can tell, there is only one network management
application running on the host.
THEORY OF OPERATION
CONNECTION ESTABLISHMENT
Communication between the SNMP Agent and its clients (sub-agents)
takes place over a stream connection. This is typically a TCP
connection, but other stream-oriented transport mechanisms can be
used. As an example, the VM SNMP agent allows DPI connections over
IUCV (Inter-User Communications Vehicle) [6, 7]. Other than the
connection establishment procedure, the protocol used is identical in
these environments.
REGISTRATION
Regardless of the connection-oriented transport mechanism used, after
establishing a connection to the SNMP agent, the sub-agent registers
the set of variables it supports. Finally, when all the variable
classes have been registered, the sub-agent then waits for requests
from the SNMP agent or generates traps as required.
DPI ARCHITECTURE
There are three requests that can be initiated by the SNMP agent:
GET, GET-NEXT and SET. These correspond directly to the three SNMP
requests that a network management station can make. The sub-agent
responds to a request with a RESPONSE packet.
There are currently two requests that can be initiated by a sub-
agent: REGISTER and TRAP.
------------------------------------------------------------------------
*---------------------------------*
| SNMP Network |
| Management Station |
| |
|---------------------------------|
| SNMP Protocol |
*---------------------------------*
A | Get A
| | GetNext | GetResponse
Trap | | Set |
| V |
*---------------------------------* *----------------------*
| SNMP Protocol | | DPI Interface |
|---------------------------------| Reply | *-----------------|
| | |<-----------| | |
| SNMP Agent | | | | Client |
| A *-----------+-> | MIB query | | |
| | | Get/Set | |----------->| | or |
| Trap| | info | SNMP | | | |
|-----+------+-------* | | trap | | SNMP |
| | V | | DPI |<-----------| | Sub-Agent |
| TCP/IP layers, | | | | | |
| Kernel | | |<-----------| | |
*---------------------------------* Register *----------------------*
------------------------------------------------------------------------
Figure 1. SNMP DPI overview
Remarks for Figure 1:
o The SNMP agent communicates with the SNMP manager via the
standard SNMP protocol.
o The SNMP agent communicates with the TCP/IP layers and kernel
(operating system) in an implementation-dependent manner. It
potentially implements the standard MIB view in this way.
o An SNMP sub-agent, running as a separate process (potentially
even on another machine), can register objects with the SNMP
agent.
o The SNMP agent will decode SNMP Packets. If such a packet
contains a Get/GetNext or Set request for an object registered
by a sub-agent, it will send the request to the sub-agent via
the corresponding query packet.
o The SNMP sub-agent sends responses back via a RESPONSE packet.
o The SNMP agent then encodes the reply into an SNMP packet and
sends it back to the requesting SNMP manager.
o If the sub-agent wants to report an important state change, it
sends a TRAP packet to the SNMP agent, which will encode it
into an SNMP trap packet and send it to the manager(s).
SNMP DPI PROTOCOL
This section describes the actual protocol used between the SNMP
agent and sub-agents. This information has not previously been
published.
CONNECTION ESTABLISHMENT
In a TCP/IP environment, the SNMP agent listens on an arbitrary TCP
port for a connection request from a sub-agent. It is important to
realize that a well-known port is not used: every invocation of the
SNMP agent will potentially result in a different TCP port being
used.
A sub-agent needs to determine this port number to establish a
connection. The sub-agent learns the port number from the agent by
sending it one conventional SNMP get-request PDU. The port number
is maintained by the SNMP agent as the object whose identifier is
1.3.6.1.4.1.2.2.1.1.0; this variable is registered under the IBM
enterprise-specific tree. The SNMP agent replies with a conventional
SNMP response PDU that contains the port number to be used. This
response is examined by the sub-agent and the port number is
extracted. The sub-agent then establishes the connection to the
specified port.
On the surface, this procedure appears to mean that the sub-agent
must be able to create and parse SNMP packets, but this is not the
case. The DPI Application Program Interface (API) has a library
routine, query_DPI_port(), which can be used to generate and parse
the required SNMP packets. This routine is very small (under 100
lines of C), so it does not greatly increase the size of any sub-
agent).
For completeness, byte-by-byte descriptions of the packets generated
by the SNMP DPI API routine query_DPI_port() are provided below.
This is probably of little interest to most readers and reading the
source to query_DPI_port() provides much of the same information.
SNMP PDU TO GET THE AGENT'S DPI PORT
As noted, before a TCP connection to the SNMP agent can be made, the
sub-agent must learn which TCP port that the agent is listening on.
To do so, it can issue an SNMP GET for an IBM enterprise-specific
variable 1.3.6.1.4.1.2.2.1.1.0.
NOTE: the object instance of ".0" is included for clarity in this
document.
The SNMP PDU can be constructed as shown below. This PDU must be
sent to UDP port 161 on the host where the agent runs (probably the
same host where the sub-agent runs).
+----------------------------------------------------------------------+
| Table 1. SNMP PDU for GET DPI_port. This is the layout of an SNMP |
| PDU for GET DPI_port |
+-----------------+-----------------+----------------------------------+
| OFFSET | VALUE | FIELD |
+-----------------+-----------------+----------------------------------+
| 0 | 0x30 | ASN.1 header |
+-----------------+-----------------+----------------------------------+
| 1 | 34 + len | pdu_length, see formula below |
+-----------------+-----------------+----------------------------------+
| 2 | 0x02 0x01 0x00 | version (integer, length=1, |
| | 0x04 | value=0), community name |
| | | (string) |
+-----------------+-----------------+----------------------------------+
| 6 | len | length of community name |
+-----------------+-----------------+----------------------------------+
| 7 | community name | |
+-----------------+-----------------+----------------------------------+
| 7 + len | 0xa0 0x1b | SNMP GET request: |
| | | request_type=0xa0, length=0x1b |
+-----------------+-----------------+----------------------------------+
| 7 + len + 2 | 0x02 0x01 0x01 | SNMP request ID: integer, |
| | | length=1, ID=1 |
+-----------------+-----------------+----------------------------------+
| 7 + len + 5 | 0x02 0x01 0x00 | SNMP error status: integer, |
| | | length=1, error=0 |
+-----------------+-----------------+----------------------------------+
| 7 + len + 8 | 0x02 0x01 0x00 | SNMP index: integer, length=1, |
| | | index=0 |
+-----------------+-----------------+----------------------------------+
| 7 + len + 11 | 0x30 0x10 | Varbind list, length=0x10 |
+-----------------+-----------------+----------------------------------+
| 7 + len + 13 | 0x30 0x0e | Varbind, length=0x0e |
+-----------------+-----------------+----------------------------------+
| 7 + len + 15 | 0x06 0x0a | Object ID, length=0x0a |
+-----------------+-----------------+----------------------------------+
| 7 + len + 17 | 0x2b 0x06 0x01 | Object instance: |
| | 0x04 0x01 0x02 | 1.3.6.1.4.1.2.2.1.1.0 |
| | 0x02 0x01 0x01 | |
| | 0x00 | |
+-----------------+-----------------+----------------------------------+
| 7 + len + 27 | 0x05 0x00 | null value, length=0 |
+-----------------+-----------------+----------------------------------+
+----------------------------------------------------------------------+
The formula to calculate the length field "pdu_length" is as follows:
pdu_length = length of version field and string tag (4 bytes)
+ length of community length field (1 byte)
+ length of community name (depends...)
+ length of SNMP GET request (29 bytes)
= 34 + length of community name
SNMP PDU CONTAINING THE RESPONSE TO THE GET
Assuming that no errors occured, then the port is returned in the last 2
octets of the received packet. The format of the packet is shown below:
+----------------------------------------------------------------------+
| Table 2. SNMP RESPONSE PDU for GET of Agent's DPI port. This is the |
| layout of an SNMP RESPONSE PDU for GET DPI_port |
+-----------------+-----------------+----------------------------------+
| OFFSET | VALUE | FIELD |
+-----------------+-----------------+----------------------------------+
| 0 | 0x30 | ASN.1 header |
+-----------------+-----------------+----------------------------------+
| 1 | 36 + len | length, see formula below |
+-----------------+-----------------+----------------------------------+
| 2 | 0x02 0x01 0x00 | version (integer, length=1, |
| | 0x04 | value=0), community name |
| | | (string) |
+-----------------+-----------------+----------------------------------+
| 6 | len | length of community name |
+-----------------+-----------------+----------------------------------+
| 7 | community name | |
+-----------------+-----------------+----------------------------------+
| 7 + len | 0xa2 0x1d | SNMP RESPONSE: |
| | | request_type=0xa2, length=0x1d |
+-----------------+-----------------+----------------------------------+
| 7 + len + 2 | 0x02 0x01 0x01 | SNMP request ID: integer, |
| | | length=1, ID=1 |
+-----------------+-----------------+----------------------------------+
| 7 + len + 5 | 0x02 0x01 0x00 | SNMP error status: integer, |
| | | length=1, error=0 |
+-----------------+-----------------+----------------------------------+
| 7 + len + 8 | 0x02 0x01 0x00 | SNMP index: integer, length=1, |
| | | index=0 |
+-----------------+-----------------+----------------------------------+
| 7 + len + 11 | 0x30 0x12 | Varbind list, length=0x12 |
+-----------------+-----------------+----------------------------------+
| 7 + len + 13 | 0x30 0x10 | Varbind, length=0x10 |
+-----------------+-----------------+----------------------------------+
| 7 + len + 15 | 0x06 0x0a | Object ID, length=0x0a |
+-----------------+-----------------+----------------------------------+
+----------------------------------------------------------------------+
+----------------------------------------------------------------------+
| Table 2. SNMP RESPONSE PDU for GET of Agent's DPI port. This is the |
| layout of an SNMP RESPONSE PDU for GET DPI_port |
+-----------------+-----------------+----------------------------------+
| OFFSET | VALUE | FIELD |
+-----------------+-----------------+----------------------------------+
| 7 + len + 17 | 0x2b 0x06 0x01 | Object instance: |
| | 0x04 0x01 0x02 | 1.3.6.1.4.1.2.2.1.1.0 |
| | 0x02 0x01 0x01 | |
| | 0x00 | |
+-----------------+-----------------+----------------------------------+
| 7 + len + 27 | 0x02 0x02 | integer, length=2 |
+-----------------+-----------------+----------------------------------+
| 7 + len + 29 | msb lsb | port number (msb, lsb) |
+-----------------+-----------------+----------------------------------+
+----------------------------------------------------------------------+
The formula to calculate the length field "pdu_length" is as follows:
pdu_length = length of version field and string tag (4 bytes)
+ length of community length field (1 byte)
+ length of community name (depends...)
+ length of SNMP RESPONSE (31 bytes)
= 36 + length of community name
SNMP DPI PACKET FORMATS
Each request to or response from the agent is constructed as a
"packet" and is written to the stream.
Each packet is prefaced with the length of the data remaining in the
packet. The length is stored in network byte order (most significant
byte first, least significant last). The receiving side will read
the packet by doing something similar to:
unsigned char len_bfr[2];
char *bfr;
int len;
read(fd,len_bfr,2);
len = len_bfr[0] * 256 + len_bfr[1];
bfr = malloc(len);
read(fd,bfr,len);
NOTE: the above example makes no provisions for error handling or a
read returning less than the requested amount of data. This is not a
suggested coding style.
The first part of every packet identifies the application protocol
being used, as well as some version information. The protocol major
version is intended to indicate in broad terms what version of the
protocol is used. The protocol minor version is intended to identify
major incompatible versions of the protocol. The protocol release is
intended to indicate incremental modifications to the protocol. The
constants that are valid for these fields are defined in Table 10 on
page 18.
The next (common) field in all packets is the packet type. This
field indicates what kind of packet we're dealing with (SNMP DPI GET,
GET-NEXT, SET, TRAP, RESPONSE or REGISTER). The permitted values for
this field are defined in Table 11 on page 18.
+----------------------------------------------------------------------+
| Table 3. SNMP DPI packet header. This header is present in all |
| packets. |
+-------------+--------------------------------------------------------+
| OFFSET | FIELD |
+-------------+--------------------------------------------------------+
| 0 | packet length to follow (MSB) |
+-------------+--------------------------------------------------------+
| 1 | packet length to follow (LSB) |
+-------------+--------------------------------------------------------+
| 2 | protocol major version |
+-------------+--------------------------------------------------------+
| 3 | protocol minor version |
+-------------+--------------------------------------------------------+
| 4 | protocol release |
+-------------+--------------------------------------------------------+
| 5 | packet type |
+-------------+--------------------------------------------------------+
+----------------------------------------------------------------------+
>From this point onwards, the contents of the packet are defined by the
protocol being used. The remainder of this section describes:
o the structure of packets for the SNMP DPI protocol, version 1.0.
o The constants as defined with this version of the protocol.
REGISTER
In order to register a branch in the MIB tree, an SNMP sub-agent
sends an SNMP DPI REGISTER packet to the agent.
Such a packet contains the standard SNMP DPI header plus REGISTER-
specific data, which basically is a null terminated string
representing the object ID in dotted ASN.1 notation (with a trailing
dot!).
+----------------------------------------------------------------------+
| Table 4. SNMP DPI REGISTER packet. This is the layout of an SNMP |
| DPI REGISTER packet |
+-------------+--------------------------------------------------------+
| OFFSET | FIELD |
+-------------+--------------------------------------------------------+
| 0 | packet length to follow (MSB) |
+-------------+--------------------------------------------------------+
| 1 | packet length to follow (LSB) |
+-------------+--------------------------------------------------------+
| 2 | protocol major version |
+-------------+--------------------------------------------------------+
| 3 | protocol minor version |
+-------------+--------------------------------------------------------+
| 4 | protocol release |
+-------------+--------------------------------------------------------+
| 5 | packet type = SNMP_DPI_REGISTER |
+-------------+--------------------------------------------------------+
| 6 | null terminated object ID |
+-------------+--------------------------------------------------------+
+----------------------------------------------------------------------+
GET
When the SNMP agent receives a PDU containing an SNMP GET request for
a variable that a sub-agent registered with the agent, it passes an
SNMP DPI GET packet to the sub-agent.
Such a packet contains the standard SNMP DPI header plus GET-specific
data, which is basically a null terminated string representing the
object ID in dotted ASN.1 notation.
+----------------------------------------------------------------------+
| Table 5. SNMP DPI GET packet. This is the layout of an SNMP DPI GET |
| packet |
+-------------+--------------------------------------------------------+
| OFFSET | FIELD |
+-------------+--------------------------------------------------------+
| 0 | packet length to follow (MSB) |
+-------------+--------------------------------------------------------+
| 1 | packet length to follow (LSB) |
+-------------+--------------------------------------------------------+
| 2 | protocol major version |
+-------------+--------------------------------------------------------+
| 3 | protocol minor version |
+-------------+--------------------------------------------------------+
| 4 | protocol release |
+-------------+--------------------------------------------------------+
| 5 | packet type = SNMP_DPI_GET |
+-------------+--------------------------------------------------------+
| 6 | null terminated object ID |
+-------------+--------------------------------------------------------+
+----------------------------------------------------------------------+
GET-NEXT
When the SNMP agent receives a PDU containing an SNMP GET-NEXT
request for a variable for which a sub-agent may be authoritative, it
passes an SNMP DPI GET-NEXT packet to the sub-agent.
Such a packet contains the standard SNMP DPI header plus GET-NEXT-
specific data. These data take the form of two null terminated
strings. The first string represents the object ID in dotted ASN.1
notation; the second string represents the group ID in dotted ASN.1
notation.
+----------------------------------------------------------------------+
| Table 6. SNMP DPI GET NEXT packet. This is the layout of an SNMP |
| DPI GET NEXT packet |
+-------------+--------------------------------------------------------+
| OFFSET | FIELD |
+-------------+--------------------------------------------------------+
| 0 | packet length to follow (MSB) |
+-------------+--------------------------------------------------------+
| 1 | packet length to follow (LSB) |
+-------------+--------------------------------------------------------+
| 2 | protocol major version |
+-------------+--------------------------------------------------------+
| 3 | protocol minor version |
+-------------+--------------------------------------------------------+
| 4 | protocol release |
+-------------+--------------------------------------------------------+
| 5 | packet type = SNMP_DPI_GET_NEXT |
+-------------+--------------------------------------------------------+
| 6 | null terminated object ID |
+-------------+--------------------------------------------------------+
| 6 + len | null terminated group ID |
+-------------+--------------------------------------------------------+
| NOTE: len=strlen(object ID)+1 |
+----------------------------------------------------------------------+
+----------------------------------------------------------------------+
SET
When the SNMP agent receives a PDU containing an SNMP SET request for
a variable that a sub-agent registered with the agent, it passes an
SNMP DPI SET packet to the sub-agent.
Such a packet contains the standard SNMP DPI header plus SET specific
data, which is basically a null terminated string representing the
object ID in ASN.1 notation, with the type, value length and value to
be set. The permitted types for the type field are defined in Table
12 on page 19. Integer values are sent as 4-byte elements in network
byte order (most significant byte first, least significant byte
last).
+----------------------------------------------------------------------+
| Table 7. SNMP DPI SET packet. This is the layout of an SNMP DPI SET |
| packet |
+-------------+--------------------------------------------------------+
| OFFSET | FIELD |
+-------------+--------------------------------------------------------+
| 0 | packet length to follow (MSB) |
+-------------+--------------------------------------------------------+
| 1 | packet length to follow (LSB) |
+-------------+--------------------------------------------------------+
| 2 | protocol major version |
+-------------+--------------------------------------------------------+
| 3 | protocol minor version |
+-------------+--------------------------------------------------------+
| 4 | protocol release |
+-------------+--------------------------------------------------------+
| 5 | packet type = SNMP_DPI_SET |
+-------------+--------------------------------------------------------+
| 6 | null terminated object ID |
+-------------+--------------------------------------------------------+
| 6 + len | SNMP Variable Type Value |
+-------------+--------------------------------------------------------+
| 6 + len + 1 | Length of value (MSB) |
+-------------+--------------------------------------------------------+
| 6 + len + 2 | Length of value (LSB) |
+-------------+--------------------------------------------------------+
| 6 + len + 3 | Value |
+-------------+--------------------------------------------------------+
| NOTE: len=strlen(object ID)+1 |
+----------------------------------------------------------------------+
+----------------------------------------------------------------------+
RESPONSE
An SNMP sub-agent must respond to a GET, GET_NEXT or SET request that
it has received from the agent (unless it fails or has a bug). To do
so, it sends an SNMP DPI RESPONSE packet to the agent.
Such a packet contains the standard SNMP DPI header plus RESPONSE
specific data, which basically is an error_code plus (if there was no
error), the name/type/value tuple representing the returned object.
This is described as by a string representing the object ID in ASN.1
notation, plus the type, value length and value of the object that
was manipulated. The permitted types for the type field are defined
in Table 12 on page 19. Integer values are sent as 4-byte elements
in network byte order (most significant byte first, least significant
byte last).
+----------------------------------------------------------------------+
| Table 8. SNMP DPI RESPONSE packet. This is the layout of an SNMP |
| DPI RESPONSE packet |
+-------------+--------------------------------------------------------+
| OFFSET | FIELD |
+-------------+--------------------------------------------------------+
| 0 | packet length to follow (MSB) |
+-------------+--------------------------------------------------------+
| 1 | packet length to follow (LSB) |
+-------------+--------------------------------------------------------+
| 2 | protocol major version |
+-------------+--------------------------------------------------------+
| 3 | protocol minor version |
+-------------+--------------------------------------------------------+
| 4 | protocol release |
+-------------+--------------------------------------------------------+
| 5 | packet type = SNMP_DPI_RESPONSE |
+-------------+--------------------------------------------------------+
| 6 | SNMP error code |
+-------------+--------------------------------------------------------+
| 7 | null terminated object ID |
+-------------+--------------------------------------------------------+
| 7 + len | SNMP Variable Type Value |
+-------------+--------------------------------------------------------+
| 7 + len + 1 | Length of value (MSB) |
+-------------+--------------------------------------------------------+
| 7 + len + 2 | Length of value (LSB) |
+-------------+--------------------------------------------------------+
| 7 + len + 3 | Value |
+-------------+--------------------------------------------------------+
| NOTE: len=strlen(object ID)+1 |
+----------------------------------------------------------------------+
+----------------------------------------------------------------------+
TRAP
An SNMP sub-agent can request the agent to generate a TRAP by sending
an SNMP DPI TRAP packet to the agent.
Such a packet contains the standard SNMP DPI header plus TRAP
specific data, which is basically the generic and specific trap code,
plus a name/type/value tuple. The tuple is described by a string
representing the object ID in ASN.1 notation, plus the type, value
length and value of the object that is being sent in the trap. The
permitted types for the type field are defined in Table 12 on page
19. Integer values are sent as 4-byte elements in network byte order
(most significant byte first, least significant byte last).
+----------------------------------------------------------------------+
| Table 9. SNMP DPI TRAP packet. This is the layout of an SNMP DPI |
| TRAP packet |
+-------------+--------------------------------------------------------+
| OFFSET | FIELD |
+-------------+--------------------------------------------------------+
| 0 | packet length to follow (MSB) |
+-------------+--------------------------------------------------------+
| 1 | packet length to follow (LSB) |
+-------------+--------------------------------------------------------+
| 2 | protocol major version |
+-------------+--------------------------------------------------------+
| 3 | protocol minor version |
+-------------+--------------------------------------------------------+
| 4 | protocol release |
+-------------+--------------------------------------------------------+
| 5 | packet type - SNMP_DPI_TRAP |
+-------------+--------------------------------------------------------+
| 6 | SNMP generic trap code |
+-------------+--------------------------------------------------------+
| 7 | SNMP specific trap code |
+-------------+--------------------------------------------------------+
| 8 | null terminated object ID |
+-------------+--------------------------------------------------------+
| 8 + len | SNMP Variable Type Value |
+-------------+--------------------------------------------------------+
| 8 + len + 1 | Length of value (MSB) |
+-------------+--------------------------------------------------------+
| 8 + len + 2 | Length of value (LSB) |
+-------------+--------------------------------------------------------+
| 8 + len + 3 | Value |
+-------------+--------------------------------------------------------+
| NOTE: len=strlen(object ID)+1 |
+----------------------------------------------------------------------+
+----------------------------------------------------------------------+
CONSTANTS AND VALUES
This section describes the constants that have been defined for this
version of the SNMP DPI Protocol.
PROTOCOL VERSION AND RELEASE VALUES
+----------------------------------------------------------------------+
| Table 10. Protocol version and release values |
+-----------------------------------+----------------------------------+
| FIELD | VALUE |
+-----------------------------------+----------------------------------+
| protocol major version | 2 (SNMP DPI protocol) |
+-----------------------------------+----------------------------------+
| protocol minor version | 1 (version 1) |
+-----------------------------------+----------------------------------+
| protocol release | 0 (release 0) |
+-----------------------------------+----------------------------------+
+----------------------------------------------------------------------+
Any other values are currently undefined.
PACKET TYPE VALUES
The packet type field can have the following values:
+----------------------------------------------------------------------+
| Table 11. Valid values for the packet type field |
+-------+--------------------------------------------------------------+
| VALUE | PACKET TYPE |
+-------+--------------------------------------------------------------+
| 1 | SNMP_DPI_GET |
+-------+--------------------------------------------------------------+
| 2 | SNMP_DPI_GET_NEXT |
+-------+--------------------------------------------------------------+
| 3 | SNMP_DPI_SET |
+-------+--------------------------------------------------------------+
| 4 | SNMP_DPI_TRAP |
+-------+--------------------------------------------------------------+
| 5 | SNMP_DPI_RESPONSE |
+-------+--------------------------------------------------------------+
| 6 | SNMP_DPI_REGISTER |
+-------+--------------------------------------------------------------+
+----------------------------------------------------------------------+
VARIABLE TYPE VALUES
The variable type field can have the following values:
+----------------------------------------------------------------------+
| Table 12. Valid values for the Value Type field |
+-------+--------------------------------------------------------------+
| VALUE | VALUE TYPE |
+-------+--------------------------------------------------------------+
| 0 | text representation |
+-------+--------------------------------------------------------------+
| 129 | number (integer) |
+-------+--------------------------------------------------------------+
| 2 | octet string |
+-------+--------------------------------------------------------------+
| 3 | object identifier |
+-------+--------------------------------------------------------------+
| 4 | empty (no value) |
+-------+--------------------------------------------------------------+
| 133 | internet address |
+-------+--------------------------------------------------------------+
| 134 | counter (unsigned) |
+-------+--------------------------------------------------------------+
| 135 | gauge (unsigned) |
+-------+--------------------------------------------------------------+
| 136 | time ticks (1/100ths seconds) |
+-------+--------------------------------------------------------------+
| 9 | display string |
+-------+--------------------------------------------------------------+
+----------------------------------------------------------------------+
NOTE: Fields which represent values that are stored as a 4-byte
integer are indicated by ORing their base type value with 128.
Error Code Values for SNMP Agent Detected Errors
The error code can have one of the following values:
+----------------------------------------------------------------------+
| Table 13. Valid values for the SNMP Agent Minor Error Code field |
+-------+--------------------------------------------------------------+
| VALUE | SNMP AGENT ERROR CODE |
+-------+--------------------------------------------------------------+
| 0 | no error |
+-------+--------------------------------------------------------------+
| 1 | too big |
+-------+--------------------------------------------------------------+
| 2 | no such name |
+-------+--------------------------------------------------------------+
| 3 | bad value |
+-------+--------------------------------------------------------------+
| 4 | read only |
+-------+--------------------------------------------------------------+
| 5 | general error |
+-------+--------------------------------------------------------------+
+----------------------------------------------------------------------+
SNMP DPI APPLICATION PROGRAM INTERFACE
This section documents an API that implements the SNMP DPI. This
information has been previously published [6, 8], but the information
provided below is more current as of May 14, 1991.
OVERVIEW OF REQUEST PROCESSING
GET PROCESSING
A GET request is the easiest to process. When the DPI packet is
parsed, the parse tree holds the object ID of the variable being
requested.
If the specified object is not supported by the sub-agent, it would
return an error indication of "no such name". No name/type/value
information would be returned.
unsigned char *cp;
cp = mkDPIresponse(SNMP_NO_SUCH_NAME,0);
If the object is recognized, then the sub-agent creates a parse tree
representing the name/type/value of the object in question (using the
DPI API routine mkDPIset()), and returns no error indication. This
is demonstrated below (a string is being returned).
char *obj_id;
unsigned char *cp;
struct dpi_set_packet *ret_value;
char *data;
/* obj_id = object ID of variable, like 1.3.6.1.2.1.1.1 */
/* should be identical to object ID sent in get request */
data = "a string to be returned";
ret_value = mkDPIset(obj_id,SNMP_TYPE_STRING,
strlen(data)+1,data);
cp = mkDPIresponse(0,ret_value);
SET PROCESSING
Processing a SET request is only slightly more difficult than a GET
request. In this case, additional information is made available in
the parse tree, namely the type, length and value to be set.
The sub-agent may return an error indication of "no such name" if the
variable is unrecognized, just as in a GET request. If the variable
is recognized, but cannot be set, an error indication of "no such
name" should be also be returned, although it is tempting to return a
"read only" error.
GET NEXT PROCESSING
GET-NEXT requests are the most complicated requests to process.
After parsing a GET-NEXT request, the parse tree will contain two
parameters. One is the object ID on which the GET-NEXT operation is
being performed. The semantics of the operation are that the sub-
agent is to return the name/type/value of the next variable it
supports whose name lexicographically follows the passed object ID.
It is important to realize that a given sub-agent may support several
discontiguous sections of the MIB tree. In such a situation it would
be incorrect to jump from one section to another. This problem is
correctly handled by examining the second parameter which is passed.
This parameter represents the "reason" why the sub-agent is being
called. It holds the prefix of the tree that the sub-agent had
indicated it supported.
If the next variable supported by the sub-agent does not begin with
that prefix, the sub-agent must return an error indication of "no
such name". If required, the SNMP agent will call upon the sub-agent
again, but pass it a different group prefix. This is illustrated in
the discussion below:
Assume there are two sub-agents. The first sub-agent registers two
distinct sections of the tree, A and C. In reality, the sub-agent
supports variables A.1 and A.2, but it correctly registers the
minimal prefix required to uniquely identify the variable class it
supports.
The second sub-agent registers a different section, B, which appears
between the two sections registered by the first agent.
If a remote management station begins dumping the MIB, starting from
A, the following sequence of queries would be performed:
Sub-agent 1 gets called:
get-next(A,A) == A.1
get-next(A.1,A) = A.2
get-next(A.2,A) = error(no such name)
Sub-agent 2 is then called:
get-next(A.2,B) = B.1
get-next(B.1,B) = error(no such name)
Sub-agent 1 gets called again:
get-next(B.1,C) = C.1
REGISTER REQUESTS
A sub-agent must register the variables it supports with the SNMP
agent. The appropriate packets may be created using the DPI API
library routine mkDPIregister().
unsigned char *cp;
cp = mkDPIregister("1.3.6.1.2.1.1.2.");
NOTE: object IDs are registered with a trailing dot (".").
TRAP REQUESTS
A sub-agent can request that the SNMP agent generate a trap for it.
The sub-agent must provide the desired values for the generic and
specific parameters of the trap. It may optionally provide a
name/type/value parameter that will be included in the trap packet.
The DPI API library routine mkDPItrap() can be used to generate the
required packet.
DPI API LIBRARY ROUTINES
This section documents Application Program Interfaces to the DPI.
QUERY_DPI_PORT()
int port;
char *hostname, *community_name;
port = query_DPI_port(hostname, community_name);
The query_DPI_port() function is used by a DPI client to determine
what TCP port number is associated with the DPI. This port number is
needed to connect() to the SNMP agent. If the port cannot be
determined, -1 is returned.
The function is passed two arguments: a string representing the
host's name or IP address and the community name to be used when
making the request.
This function enables a DPI client to "bootstrap" itself. The port
number is obtained via an SNMP GET request, but the DPI client does
not have to be able to create and parse SNMP packets--this is all
done by the query_DPI_port() function.
NOTE: the query_DPI_port() function assumes that the community name
does not contain any null characters. If this is not the case, use
the _query_DPI_port() function which takes a third parameter, the
length of the community name.
MKDPIREGISTER
#include "snmp_dpi.h"
unsigned char *packet;
int len;
/* register sysDescr variable */
packet = mkDPIregister("1.3.6.1.2.1.1.1.");
len = *packet * 256 + *(packet + 1);
len += 2; /* include length bytes */
The mkDPIregister() function creates the necessary register-request
packet and returns a pointer to a static buffer holding the packet
contents. The null pointer (0) is returned if there is an error
detected during the creation of the packet.
The length of the remainder packet is stored in the first two bytes
of the packet, as demonstrated in the example above.
NOTE: object identifiers are registered with a trailing dot (".").
MKDPISET
#include "snmp_dpi.h"
struct dpi_set_packet *set_value;
char *obj_id;
int type, length;
char *value;
set_value = mkDPIset(obj_id, type, length, value);
The mkDPIset() function can be used to create the portion of a parse
tree that represents a name/value pair (as would be normally be
returned in a response packet). It returns a pointer to a
dynamically allocated parse tree representing the name/type/value
information. If there is an error detected while creating the parse
tree, the null pointer (0) is returned.
The value of type can be one of the following (which are defined in
the include file "snmp_dpi.h"):
o SNMP_TYPE_NUMBER
o SNMP_TYPE_STRING
o SNMP_TYPE_OBJECT
o SNMP_TYPE_INTERNET
o SNMP_TYPE_COUNTER
o SNMP_TYPE_GAUGE
o SNMP_TYPE_TICKS
The value parameter is always a pointer to the first byte of the
object's value.
NOTE: the parse tree is dynamically allocated and copies are made of
the passed parameters. After a successful call to mkDPIset(), they
can be disposed of in any manner the application chooses without
affecting the parse tree contents.
MKDPIRESPONSE
#include "snmp_dpi.h"
unsigned char *packet;
int error_code;
struct dpi_set_packet *ret_value;
packet = mkDPIresponse(error_code, ret_value);
len = *packet * 256 + *(packet + 1);
len += 2; /* include length bytes */
The mkDPIresponse() function creates an appropriate response packet.
It takes two parameters. The first is the error code to be returned.
It may be 0 (indicating no error) or one of the following (which are
defined in the include file "snmp_dpi.h"):
o SNMP_NO_ERROR
o SNMP_TOO_BIG
o SNMP_NO_SUCH_NAME
o SNMP_BAD_VALUE
o SNMP_READ_ONLY
o SNMP_GEN_ERR
If the error code indicates no error, then the second parameter is a
pointer to a parse tree (created by mkDPIset()) which represents the
name/type/value information being returned. If an error is
indicated, the second parameter is passed as a null pointer (0).
If the packet can be created, a pointer to a static buffer containing
the packet contents is returned. This is the same buffer used by
mkDPIregister(). If an error is encountered while creating the
packet, the null pointer (0) is returned.
The length of the remainder packet is stored in the first two bytes
of the packet, as demonstrated in the example above.
NOTE: mkDPIresponse() always frees the passed parse tree.
MKDPITRAP
#include "snmp_dpi.h"
unsigned char *packet;
int generic, specific;
struct dpi_set_packet *ret_value;
packet = mkDPItrap(generic, specific, ret_value);
len = *packet * 256 + *(packet + 1);
len += 2; /* include length bytes */
The mkDPItrap() function creates an appropriate trap request packet.
The first two parameters correspond to to value of the generic and
specific fields in the SNMP trap packet. The third field can be used
to pass a name/value pair to be provided in the SNMP trap packet.
This information is passed as the set-packet portion of the parse
tree. As an example, a linkDown trap for interface 3 might be
generated by the following:
struct dpi_set_packet *if_index_value;
unsigned long data;
unsigned char *packet;
int len;
data = 3; /* interface number = 3 */
if_index_value = mkDPIset("1.3.6.1.2.1.2.2.1.1", SNMP_TYPE_NUMBER,
sizeof(unsigned long), &data);
packet = mkDPItrap(2, 0, if_index_value);
len = *packet * 256 + *(packet + 1);
len += 2; /* include length bytes */
write(fd,packet,len);
If the packet can be created, a pointer to a static buffer containing
the packet contents is returned. This is the same buffer used by
mkDPIregister(). If an error is encountered while creating the
packet, the null pointer (0) is returned.
The length of the remainder packet is stored in the first two bytes
of the packet, as demonstrated in the example above.
NOTE: mkDPItrap() always frees the passed parse tree.
PDPIPACKET
#include "snmp_dpi.h"
unsigned char *packet;
struct snmp_dpi_hdr *hdr;
hdr = pDPIpacket(packet)
The pDPIpacket() function parses a DPI packet and returns a parse
tree representing its contents. The parse tree is dynamically
allocated and contains copies of the information within the DPI
packet. After a successful call to pDPIpacket(), the packet may be
disposed of in any manner the application chooses without affecting
the contents of the parse tree. If an error is encountered during
the parse, the null pointer (0) is returned.
NOTE: the relevant parse tree structures are defined in the include
file "snmp_dpi.h", and that file remains the definitive reference.
The root of the parse tree is represented by a snmp_dpi_hdr
structure:
struct snmp_dpi_hdr {
unsigned char proto_major;
unsigned char proto_minor;
unsigned char proto_release;
unsigned char packet_type;
union {
struct dpi_get_packet *dpi_get;
struct dpi_next_packet *dpi_next;
struct dpi_set_packet *dpi_set;
struct dpi_resp_packet *dpi_response;
struct dpi_trap_packet *dpi_trap;
} packet_body;
};
The field of immediate interest is packet_type. This field can have
one of the following values (which are defined in the include file
"snmp_dpi.h"):
o SNMP_DPI_GET
o SNMP_DPI_GET_NEXT
o SNMP_DPI_SET
The packet_type field indicates what request is being made of the DPI
client. For each of these requests, the remainder of the packet_body
will be different.
If a get request is indicated, the object ID of the desired variable
is passed in a dpi_get_packet structure:
struct dpi_get_packet {
char *object_id;
};
A get-next request is similar, but the dpi_next_packet structure also
contains the object ID prefix of the group that is currently being
traversed:
struct dpi_next_packet {
char *object_id;
char *group_id;
};
If the next object whose object ID lexicographically follows the
object ID indicated by object_id does not begin with the suffix
indicated by group_id, the DPI client must return an error indication
of SNMP_NO_SUCH_NAME.
A set request has the most amount of data associated with it and this
is contained in a dpi_set_packet structure:
struct dpi_set_packet {
char *object_id;
unsigned char type;
unsigned short value_len;
char *value;
};
The object ID of the variable to be modified is indicated by
object_id The type of the variable is provided in type and may have
one of the following values:
o SNMP_TYPE_NUMBER
o SNMP_TYPE_STRING
o SNMP_TYPE_OBJECT
o SNMP_TYPE_EMPTY
o SNMP_TYPE_INTERNET
o SNMP_TYPE_COUNTER
o SNMP_TYPE_GAUGE
o SNMP_TYPE_TICKS
The length of the value to be set is stored in value_len and value
contains a pointer to the value.
NOTE: the storage pointed to by value will be reclaimed when the
parse tree is freed. The DPI client must make provision for copying
the value contents.
FDPIPARSE
#include "snmp_dpi.h"
struct snmp_dpi_hdr *hdr;
fDPIparse(hdr);
The routine fDPIparse() frees a parse tree previously created by a
call to pDPIpacket This routine is declared as void--it has no return
value.
NOTE: after calling fDPIparse(), no further references to the parse
tree can be made.
AGENT IMPLEMENTATION ISSUES
Although the SNMP DPI protocol is completely documented in this
paper, the document itself is somewhat biased towards clearly
defining the interface provided to sub-agents (i.e., it provides a
specification of a C language API). This detailed coverage is
possible because the client side of the interface is completely
self-contained.
The agent side of the interface has to be integrated into individual
vendor implementations, many of which may have a unique
organizational structure in an attempt to address various performance
and storage constraints. This makes it infeasible to provide much
more than suggestions for SNMP agent implementers. Unfortunately,
this leaves room for a large amount of interpretation which can lead
to implementations that don't necessarily work they way they should-
-too much ambiguity can be a bad thing.
The following characteristics of an agent implementation are to be
considered mandatory:
DUPLICATE REGISTRATIONS
With this release of the protocol, order of registration is
significant. The last sub-agent to register a variable is the one
that is deemed to be authoritative. Variables implemented by the
base SNMP agent are considered to have been registered prior to any
sub-agent registrations. Thus sub-agents may re-implement support
for variables that were incorrectly implemented by a vendor.
AUTOMATIC DEREGISTRATION ON CLOSE
All SNMP DPI connections are carried over a stream connection. When
the connection is closed by the client (no matter what the cause),
the agent must automatically unregister all of the variables that
were registered by the sub-agent.
TIMELY RESPONSE CONSTRAINTS
A sub-agent must respond to a request in a timely fashion. In this
version of the protocol, we specify that a sub-agent must respond to
a request by the SNMP agent within 5 seconds. If the sub-agent does
not respond in time, the SNMP agent should terminate the connection
and unregister all of the variables that were previously registered
by the sub-agent in question.
NOTE: agent implementations that do not have access to a timer may
not be able to implement this. In that case, they leave themselves
open to being placed in a state where they are blocked forever if the
sub-agent malfunctions.
SUPPORT FOR MULTIPLE MIB VIEWS
Some agents allow different MIB views to be selected based on the
community name used. It is not the intention of this document to
pass judgement on the various approaches that have been proposed or
implemented, but instead merely to recognize the existence of
implementations that support this feature.
The point of this discussion is to specify clearly that objects
supported by an SNMP DPI sub-agent are to be registered under the MIB
view that was selected by the community name used in the SNMP GET
request that obtained the DPI_port value.
The SNMP DPI does not specify a reserved port, but instead sub-agents
bootstrap themselves by making an SNMP GET request for the DPI_port
variable. This variable represents the TCP port to which the sub-
agent should connect. It should be understood that there is no
reason why the SNMP agent cannot have several listens (passive opens)
active, each corresponding to a distinct MIB view. The port number
returned then would be different based on the community name used in
the SNMP GET request for the DPI_port variable.
CONSIDERATIONS FOR THE NEXT RELEASE
The SNMP DPI protocol makes provision for extension and parallel use
of potentially incompatible releases. The discussion above documents
the protocol as it is currently in use and has not discussed features
of interest that should be considered for a future revision.
UNREGISTER
For closure, an UNREGISTER request could be of use.
SUPPORT FOR ATOMIC SETS
The SNMP protocol [1] specifies that:
Each variable assignment specified by the SetRequest-PDU should be
effected as if simultaneously set with respect to all other
assignments specified in the same message.
The SNMP DPI has no provision for backing out a successfully
processed SET request if one of the subsequent variable assignments
fails. This omission is a reflection of several biases:
o the SNMP DPI was intended to be light-weight.
o a belief that the SNMP RFC prescribes semantics which are infeasible
to implement unless the range of applications is restricted.
It has been suggested that a new request, TEST_SET, be added to the
DPI protocol. Processing of a SET request would then be performed as
follows:
o all variables would be processed using TEST_SET unless any error
occurred. The subagents would verify that they could process the
request.
o if no error occurred, each of the variables would be reprocessed,
this time with a SET request.
A problem with such an approach is that it relies on the TEST_SET
operation to make an assertion that the request can be successfully
performed. If this is not possible, then it cannot be asserted that
the prescribed semantics will be provided. Such situations do exist,
for example, a SET request that causes the far-end channel service
unit to be looped up--one does not know if the operation will be
successful until it is performed.
SAMPLE SNMP DPI API IMPLEMENTATION
The following C language sources show an example implementation of
the SNMP DPI Application Programming Interface as it would be exposed
to the sub-agents.
SAMPLE SNMP DPI INCLUDE FILE
/* SNMP distributed program interface */
#define SNMP_DPI_GET 1
#define SNMP_DPI_GET_NEXT 2
#define SNMP_DPI_SET 3
#define SNMP_DPI_TRAP 4
#define SNMP_DPI_RESPONSE 5
#define SNMP_DPI_REGISTER 6
#define SNMP_DPI_PROTOCOL 2
#define SNMP_DPI_VERSION 1
#define SNMP_DPI_RELEASE 0
/* SNMP error codes from RFC 1098 (1067) */
#define SNMP_NO_ERROR 0
#define SNMP_TOO_BIG 1
#define SNMP_NO_SUCH_NAME 2
#define SNMP_BAD_VALUE 3
#define SNMP_READ_ONLY 4
#define SNMP_GEN_ERR 5
/* variable types */
#define SNMP_TYPE_TEXT 0 /* textual representation */
#define SNMP_TYPE_NUMBER (128|1) /* number */
#define SNMP_TYPE_STRING 2 /* text string */
#define SNMP_TYPE_OBJECT 3 /* object identifier */
#define SNMP_TYPE_EMPTY 4 /* no value */
#define SNMP_TYPE_INTERNET (128|5) /* internet address */
#define SNMP_TYPE_COUNTER (128|6) /* counter */
#define SNMP_TYPE_GAUGE (128|7) /* gauge */
#define SNMP_TYPE_TICKS (128|8) /* time ticks (1/100th sec) */
#define SNMP_TYPE_MASK 0x7f /* mask for type */
struct dpi_get_packet {
char *object_id;
};
struct dpi_next_packet {
char *object_id;
char *group_id;
};
struct dpi_set_packet {
char *object_id;
unsigned char type;
unsigned short value_len;
char *value;
};
struct dpi_resp_packet {
unsigned char ret_code;
struct dpi_set_packet *ret_data;
};
struct dpi_trap_packet {
unsigned char generic;
unsigned char specific;
struct dpi_set_packet *info;
};
struct snmp_dpi_hdr {
unsigned char proto_major;
unsigned char proto_minor;
unsigned char proto_release;
unsigned char packet_type;
union {
struct dpi_get_packet *dpi_get;
struct dpi_next_packet *dpi_next;
struct dpi_set_packet *dpi_set;
struct dpi_resp_packet *dpi_response;
struct dpi_trap_packet *dpi_trap;
} packet_body;
};
extern struct snmp_dpi_hdr *pDPIpacket();
extern void fDPIparse();
extern unsigned char *mkMIBquery();
extern unsigned char *mkDPIregister();
extern unsigned char *mkDPIresponse();
extern unsigned char *mkDPItrap();
extern struct dpi_set_packet *mkDPIset();
SAMPLE QUERY_DPI_PORT() FUNCTION
#ifdef VM
#include <manifest.h>
#include <snmp_vm.h>
#include <bsdtime.h>
#include <bsdtypes.h>
#include <socket.h>
#include <in.h>
#include <netdb.h>
#include <inet.h>
#else
#include <sys/time.h>
#include <sys/types.h>
#include <sys/socket.h>
#include <netinet/in.h>
#include <netdb.h>
#include <arpa/inet.h>
#endif
static unsigned char asn1_hdr[] = {0x30};
/* insert length of remaining packet, not including this */
static unsigned char version[] = {0x02, 0x01, 0x00, 0x04};
/* integer, len=1, value=0, string */
/* insert community name length and community name */
static unsigned char request[] = {
0xa0, 0x1b, /* get request, len=0x1b */
0x02, 0x01, 0x01, /* integer, len=1,request_id = 1 */
0x02, 0x01, 0x00, /* integer, len=1, error_status = 0 */
0x02, 0x01, 0x00, /* integer, len=1, error_index = 0 */
0x30, 0x10, /* varbind list, len=0x10 */
0x30, 0x0e, /* varbind , len=0x0e */
0x06, 0x0a, /* object ID, len=0x0a */
0x2b, 0x06, 0x01, 0x04, 0x01, 0x02, 0x02, 0x01, 0x01, 0x00,
0x05, 0x00 /* value, len = 0 */
};
static extract_DPI_port();
query_DPI_port(hostname, community_name)
char *hostname;
char *community_name;
{
int community_len;
int rc;
community_len = strlen(community_name);
rc = _query_DPI_port(hostname, community_name, community_len);
return (rc);
}
/* use if community_name has embedded nulls */
_query_DPI_port(hostname, community_name, community_len)
char *hostname;
char *community_name;
int community_len;
{
unsigned char packet[1024];
int packet_len;
int remaining_len;
int fd, rc, sock_len;
struct sockaddr_in sock, dest_sock;
struct timeval timeout;
unsigned long host_addr, read_mask;
int tries;
host_addr = lookup_host(hostname);
packet_len = 0;
bcopy(asn1_hdr, packet, sizeof(asn1_hdr));
packet_len += sizeof(asn1_hdr);
remaining_len = sizeof(version) + 1 +
community_len + sizeof(request);
packet[packet_len++] = remaining_len & 0xff;
bcopy(version, packet + packet_len, sizeof(version));
packet_len += sizeof(version);
packet[packet_len++] = community_len & 0xff;
bcopy(community_name, packet + packet_len, community_len);
packet_len += community_len;
bcopy(request, packet + packet_len, sizeof(request));
packet_len += sizeof(request);
fd = socket(AF_INET, SOCK_DGRAM, 0);
if (fd < 0) {
return (-1);
}
bzero(&sock, sizeof(sock));
sock.sin_family = AF_INET;
sock.sin_port = 0;
sock.sin_addr.s_addr = 0;
rc = bind(fd, &sock, sizeof(sock));
if (rc < 0)
return (-1);
timeout.tv_sec = 3;
timeout.tv_usec = 0;
bzero(&dest_sock, sizeof(dest_sock));
dest_sock.sin_family = AF_INET;
dest_sock.sin_port = htons(161);
dest_sock.sin_addr.s_addr = host_addr;
tries = 0;
while (++tries < 4) {
rc = sendto(fd, packet, packet_len, 0, &dest_sock,
sizeof(dest_sock));
read_mask = 1 << fd;
rc = select(read_mask + 1, &read_mask, 0, 0, &timeout);
if (rc <= 0)
continue;
sock_len = sizeof(dest_sock);
packet_len = recvfrom(fd, packet, sizeof(packet), 0,
&dest_sock, &sock_len);
if (packet_len <= 0) {
return (-1);
}
rc = extract_DPI_port(packet, packet_len);
return (rc);
}
return (-1);
}
static extract_DPI_port(packet, len)
unsigned char packet[];
int len;
{
int offset;
int port;
/* should do error checking (like for noSuchName) */
offset = len - 2;
port = (packet[offset] << 8) + packet[offset + 1];
return (port);
}
SAMPLE DPI FUNCTIONS
/* DPI parser */
#ifdef VM
#include "manifest.h"
#endif
#include "snmp_dpi.h"
static struct dpi_get_packet *pDPIget();
static struct dpi_next_packet *pDPInext();
static struct dpi_set_packet *pDPIset();
static struct dpi_trap_packet *pDPItrap();
static struct dpi_resp_packet *pDPIresponse();
static void fDPIget();
static void fDPInext();
static void fDPIset();
static void fDPItrap();
static void fDPIresponse();
static int cDPIget();
static int cDPInext();
static int cDPIset();
static int cDPItrap();
static int cDPIresponse();
static struct snmp_dpi_hdr *mkDPIhdr();
static struct dpi_get_packet *mkDPIget();
static struct dpi_next_packet *mkDPInext();
struct dpi_set_packet *mkDPIset();
extern char *malloc();
static unsigned char new_packet[1024];
static int packet_len;
struct snmp_dpi_hdr *pDPIpacket(packet)
unsigned char *packet;
{
struct snmp_dpi_hdr *hdr;
int len, offset;
hdr = (struct snmp_dpi_hdr *) malloc(sizeof(struct snmp_dpi_hdr));
if (hdr == 0)
return (0);
len = (packet[0] << 8) + packet[1];
len += 2;
offset = 2;
hdr->proto_major = packet[offset++];
hdr->proto_minor = packet[offset++];
hdr->proto_release = packet[offset++];
hdr->packet_type = packet[offset++];
switch (hdr->packet_type) {
case SNMP_DPI_GET:
case SNMP_DPI_REGISTER:
hdr->packet_body.dpi_get =
pDPIget(packet + offset, len - offset);
break;
case SNMP_DPI_GET_NEXT:
hdr->packet_body.dpi_next =
pDPInext(packet + offset, len - offset);
break;
case SNMP_DPI_SET:
hdr->packet_body.dpi_set =
pDPIset(packet + offset, len - offset);
break;
case SNMP_DPI_TRAP:
hdr->packet_body.dpi_trap =
pDPItrap(packet + offset, len - offset);
break;
case SNMP_DPI_RESPONSE:
hdr->packet_body.dpi_response =
pDPIresponse(packet + offset, len - offset);
break;
}
return (hdr);
}
static struct dpi_get_packet *pDPIget(packet, len)
unsigned char *packet;
int len;
{
struct dpi_get_packet *get;
int l;
get = (struct dpi_get_packet *)
malloc(sizeof(struct dpi_get_packet));
if (get == 0)
return (0);
l = strlen(packet) + 1;
get->object_id = malloc(l);
strcpy(get->object_id, packet);
return (get);
}
static struct dpi_next_packet *pDPInext(packet, len)
unsigned char *packet;
int len;
{
struct dpi_next_packet *next;
int l;
unsigned char *cp;
next = (struct dpi_next_packet *)
malloc(sizeof(struct dpi_next_packet));
if (next == 0)
return (0);
cp = packet;
l = strlen(cp) + 1;
next->object_id = malloc(l);
strcpy(next->object_id, cp);
cp += l;
l = strlen(cp) + 1;
next->group_id = malloc(l);
strcpy(next->group_id, cp);
return (next);
}
static struct dpi_set_packet *pDPIset(packet, len)
unsigned char *packet;
int len;
{
struct dpi_set_packet *set;
int l;
unsigned char *cp;
if (len == 0)
return (0); /* nothing to parse */
set = (struct dpi_set_packet *)
malloc(sizeof(struct dpi_set_packet));
if (set == 0)
return (0);
cp = packet;
l = strlen(cp) + 1;
set->object_id = malloc(l);
strcpy(set->object_id, cp);
cp += l;
set->type = *(cp++);
l = (*(cp++) << 8);
l += *(cp++);
set->value_len = l;
set->value = malloc(l);
bcopy(cp, set->value, l);
return (set);
}
static struct dpi_trap_packet *pDPItrap(packet, len)
unsigned char *packet;
int len;
{
struct dpi_trap_packet *trap;
trap = (struct dpi_trap_packet *)
malloc(sizeof(struct dpi_trap_packet));
if (trap == 0)
return (0);
trap->generic = *packet;
trap->specific = *(packet + 1);
trap->info = pDPIset(packet + 2, len - 2);
return (trap);
}
static struct dpi_resp_packet *pDPIresponse(packet, len)
unsigned char *packet;
int len;
{
struct dpi_resp_packet *resp;
resp = (struct dpi_resp_packet *)
malloc(sizeof(struct dpi_resp_packet));
if (resp == 0)
return (0);
resp->ret_code = *packet;
resp->ret_data = pDPIset(packet + 1, len - 1);
return (resp);
}
void fDPIparse(hdr)
struct snmp_dpi_hdr *hdr;
{
if (hdr == 0)
return;
switch (hdr->packet_type) {
case SNMP_DPI_GET:
case SNMP_DPI_REGISTER:
fDPIget(hdr);
break;
case SNMP_DPI_GET_NEXT:
fDPInext(hdr);
break;
case SNMP_DPI_SET:
fDPIset(hdr);
break;
case SNMP_DPI_TRAP:
fDPItrap(hdr);
break;
case SNMP_DPI_RESPONSE:
fDPIresponse(hdr);
break;
}
free(hdr);
}
static void fDPIget(hdr)
struct snmp_dpi_hdr *hdr;
{
struct dpi_get_packet *get;
get = hdr->packet_body.dpi_get;
if (get == 0)
return;
if (get->object_id)
free(get->object_id);
free(get);
}
static void fDPInext(hdr)
struct snmp_dpi_hdr *hdr;
{
struct dpi_next_packet *next;
next = hdr->packet_body.dpi_next;
if (next == 0)
return;
if (next->object_id)
free(next->object_id);
if (next->group_id)
free(next->group_id);
free(next);
}
static void fDPIset(hdr)
struct snmp_dpi_hdr *hdr;
{
struct dpi_set_packet *set;
set = hdr->packet_body.dpi_set;
if (set == 0)
return;
if (set->object_id)
free(set->object_id);
if (set->value)
free(set->value);
free(set);
}
static void fDPItrap(hdr)
struct snmp_dpi_hdr *hdr;
{
struct dpi_trap_packet *trap;
struct dpi_set_packet *set;
trap = hdr->packet_body.dpi_trap;
if (trap == 0)
return;
set = trap->info;
if (set != 0) {
if (set->object_id)
free(set->object_id);
if (set->value)
free(set->value);
free(set);
}
free(trap);
}
static void fDPIresponse(hdr)
struct snmp_dpi_hdr *hdr;
{
struct dpi_resp_packet *resp;
struct dpi_set_packet *set;
resp = hdr->packet_body.dpi_response;
if (resp == 0)
return;
set = resp->ret_data;
if (set != 0) {
if (set->object_id)
free(set->object_id);
if (set->value)
free(set->value);
free(set);
}
free(resp);
}
unsigned char *cDPIpacket(hdr)
struct snmp_dpi_hdr *hdr;
{
int rc, len;
if (hdr == 0) {
return (0);
}
packet_len = 2;
new_packet[packet_len++] = hdr->proto_major;
new_packet[packet_len++] = hdr->proto_minor;
new_packet[packet_len++] = hdr->proto_release;
new_packet[packet_len++] = hdr->packet_type;
switch (hdr->packet_type) {
case SNMP_DPI_GET:
case SNMP_DPI_REGISTER:
rc = cDPIget(hdr->packet_body.dpi_get);
break;
case SNMP_DPI_GET_NEXT:
rc = cDPInext(hdr->packet_body.dpi_next);
break;
case SNMP_DPI_SET:
rc = cDPIset(hdr->packet_body.dpi_set);
break;
case SNMP_DPI_TRAP:
rc = cDPItrap(hdr->packet_body.dpi_trap);
break;
case SNMP_DPI_RESPONSE:
rc = cDPIresponse(hdr->packet_body.dpi_response);
break;
}
if (rc == -1)
return (0);
len = packet_len - 2;
new_packet[1] = len & 0xff;
len >>= 8;
new_packet[0] = len & 0xff;
return (new_packet);
}
static int cDPIget(get)
struct dpi_get_packet *get;
{
if (get->object_id == 0)
return (-1);
strcpy(&new_packet[packet_len], get->object_id);
packet_len += strlen(get->object_id) + 1;
return (0);
}
static int cDPInext(next)
struct dpi_next_packet *next;
{
if (next->object_id == 0)
return (-1);
if (next->group_id == 0)
return (-1);
strcpy(&new_packet[packet_len], next->object_id);
packet_len += strlen(next->object_id) + 1;
strcpy(&new_packet[packet_len], next->group_id);
packet_len += strlen(next->group_id) + 1;
return (0);
}
static int cDPIset(set)
struct dpi_set_packet *set;
{
int len;
if (set->object_id == 0)
return (-1);
if ((set->value == 0) && (set->value_len != 0))
return (-1);
strcpy(&new_packet[packet_len], set->object_id);
packet_len += strlen(set->object_id) + 1;
new_packet[packet_len++] = set->type;
len = set->value_len >> 8;
new_packet[packet_len++] = len & 0xff;
new_packet[packet_len++] = set->value_len & 0xff;
bcopy(set->value, &new_packet[packet_len], set->value_len);
packet_len += set->value_len;
return (0);
}
static int cDPIresponse(resp)
struct dpi_resp_packet *resp;
{
int rc;
if (resp == 0)
return (-1);
new_packet[packet_len++] = resp->ret_code;
if (resp->ret_data != 0) {
rc = cDPIset(resp->ret_data);
} else
rc = 0;
return (rc);
}
static int cDPItrap(trap)
struct dpi_trap_packet *trap;
{
int rc;
new_packet[packet_len++] = trap->generic;
new_packet[packet_len++] = trap->specific;
if (trap->info != 0)
rc = cDPIset(trap->info);
else
rc = 0;
return (rc);
}
unsigned char *mkMIBquery(cmd, oid_name, group_oid, type, len, value)
int cmd;
char *oid_name, *group_oid;
int type, len;
char *value;
{
struct snmp_dpi_hdr *hdr;
unsigned char *cp;
hdr = mkDPIhdr(cmd);
if (hdr == 0)
return (0);
switch (hdr->packet_type) {
case SNMP_DPI_GET:
case SNMP_DPI_REGISTER:
hdr->packet_body.dpi_get = mkDPIget(oid_name);
break;
case SNMP_DPI_GET_NEXT:
hdr->packet_body.dpi_next = mkDPInext(oid_name, group_oid);
break;
case SNMP_DPI_SET:
hdr->packet_body.dpi_set =
mkDPIset(oid_name, type, len, value);
break;
}
cp = cDPIpacket(hdr);
fDPIparse(hdr);
return (cp);
}
unsigned char *mkDPIregister(oid_name)
char *oid_name;
{
return (mkMIBquery(SNMP_DPI_REGISTER, oid_name));
}
unsigned char *mkDPIresponse(ret_code, value_list)
int ret_code;
struct dpi_set_packet *value_list;
{
struct snmp_dpi_hdr *hdr;
struct dpi_resp_packet *resp;
unsigned char *cp;
hdr = mkDPIhdr(SNMP_DPI_RESPONSE);
resp = (struct dpi_resp_packet *)
malloc(sizeof(struct dpi_resp_packet));
if (resp == 0) {
free(hdr);
return (0);
}
hdr->packet_body.dpi_response = resp;
resp->ret_code = ret_code;
resp->ret_data = value_list;
cp = cDPIpacket(hdr);
fDPIparse(hdr);
return (cp);
}
unsigned char *mkDPItrap(generic, specific, value_list)
int generic, specific;
struct dpi_set_packet *value_list;
{
struct snmp_dpi_hdr *hdr;
struct dpi_trap_packet *trap;
unsigned char *cp;
hdr = mkDPIhdr(SNMP_DPI_TRAP);
trap = (struct dpi_trap_packet *)
malloc(sizeof(struct dpi_trap_packet));
if (trap == 0) {
free(hdr);
return (0);
}
hdr->packet_body.dpi_trap = trap;
trap->generic = generic;
trap->specific = specific;
trap->info = value_list;
cp = cDPIpacket(hdr);
fDPIparse(hdr);
return (cp);
}
static struct snmp_dpi_hdr *mkDPIhdr(type)
int type;
{
struct snmp_dpi_hdr *hdr;
hdr = (struct snmp_dpi_hdr *) malloc(sizeof(struct snmp_dpi_hdr));
if (hdr == 0)
return (0);
hdr->proto_major = SNMP_DPI_PROTOCOL;
hdr->proto_minor = SNMP_DPI_VERSION;
hdr->proto_release = SNMP_DPI_RELEASE;
hdr->packet_type = type;
return (hdr);
}
static struct dpi_get_packet *mkDPIget(oid_name)
char *oid_name;
{
struct dpi_get_packet *get;
int l;
get = (struct dpi_get_packet *)
malloc(sizeof(struct dpi_get_packet));
if (get == 0)
return (0);
l = strlen(oid_name) + 1;
get->object_id = malloc(l);
strcpy(get->object_id, oid_name);
return (get);
}
static struct dpi_next_packet *mkDPInext(oid_name, group_oid)
char *oid_name;
char *group_oid;
{
struct dpi_next_packet *next;
int l;
next = (struct dpi_next_packet *)
malloc(sizeof(struct dpi_next_packet));
if (next == 0)
return (0);
l = strlen(oid_name) + 1;
next->object_id = malloc(l);
strcpy(next->object_id, oid_name);
l = strlen(group_oid) + 1;
next->group_id = malloc(l);
strcpy(next->group_id, group_oid);
return (next);
}
struct dpi_set_packet *mkDPIset(oid_name, type, len, value)
char *oid_name;
int type;
int len;
char *value;
{
struct dpi_set_packet *set;
int l;
set = (struct dpi_set_packet *)
malloc(sizeof(struct dpi_set_packet));
if (set == 0)
return (0);
l = strlen(oid_name) + 1;
set->object_id = malloc(l);
strcpy(set->object_id, oid_name);
set->type = type;
set->value_len = len;
set->value = malloc(len);
bcopy(value, set->value, len);
return (set);
}
SAMPLE SOURCES FOR ANONYMOUS FTP
The complete source to two SNMP DPI-related programs is available for
anonymous ftp from the University of Toronto. The host name to use
is "vm.utcs.utoronto.ca" (128.100.100.2). The files are in the
"anonymou.204" minidisk, so one must issue a "cd anonymou.204" after
having logged in. Don't forget to use the binary transmission mode.
The Ping Engine
This program is an SNMP DPI sub-agent which allows network management
stations to perform remote PINGs. The source to this applications is
in the file "ping_eng.tarbin". The source to the SNMP DPI API is
also contained within the archive.
The DPI->SMUX daemon
This program illustrates what is required to include the SNMP DPI in
an SNMP agent. This is actually a SMUX-based agent that works with
the ISODE SNMP agent and provides an interface for SNMP DPI sub-
agents. The source to this program is in the file "dpid.tarbin".
ISODE 6.7, or later, is a prerequisite.
References
[1] Case, J., Fedor, M., Schoffstall, M., and J. Davin, "Simple
Network Management Protocol", RFC 1157, SNMP Research,
Performance Systems International, Performance Systems
International, MIT Laboratory for Computer Science, May 1990.
[2] Information processing systems - Open Systems Interconnection,
"Specification of Abstract Syntax Notation One (ASN.1)",
International Organization for Standardization, International
Standard 8824, December 1987.
[3] Information processing systems - Open Systems Interconnection,
"Specification of Basic Encoding Rules for Abstract Syntax
Notation One (ASN.1)", International Organization for
Standardization, International Standard 8825, December 1987.
[4] McCloghrie K., and M. Rose, "Management Information Base for
Network Management of TCP/IP-based internets", RFC 1156,
Performance Systems International and Hughes LAN Systems, May
1990.
[5] Rose, M., and K. McCloghrie, "Structure and Identification of
Management Information for TCP/IP-based internets", RFC 1155,
Performance Systems International and Hughes LAN Systems, May
1990.
[6] International Business Machines, Inc., "TCP/IP for VM:
Programmer's Reference", SC31-6084-0, 1990.
[7] International Business Machines, Inc., "Virtual Machine System
Facilities for Programming, Release 6", SC24-5288-01, 1988.
[8] International Business Machines, Inc., "TCP/IP Version 1.1 for
OS/2 EE: Programmer's Reference", SC31-6077-1, 1990.
Security Considerations
Security issues are not discussed in this memo.
Authors' Addresses
Geoffrey C. Carpenter
IBM T. J. Watson Research Center
P. O. Box 218
Yorktown Heights, NY 10598
Phone: (914) 945-1970
Email: gcc@watson.ibm.com
Bert Wijnen
IBM International Operations
Watsonweg 2
1423 ND Uithoorn
The Netherlands
Phone: +31-2975-53316
Email: wijnen@uitvm2.iinus1.ibm.com