14. Client Classification¶
14.1. Client Classification Overview¶
In certain cases it is useful to differentiate among different types of clients and treat them accordingly. Common reasons include:
- The clients represent different pieces of topology, e.g. a cable modem is not the same as the clients behind that modem.
- The clients have different behavior, e.g. a smartphone behaves differently from a laptop.
- The clients require different values for some options, e.g. a docsis3.0 cable modem requires different settings from a docsis2.0 cable modem.
To make management easier, different clients can be grouped into a client class to receive common options.
An incoming packet can be associated with a client class in several ways:
- Implicitly, using a vendor class option or another built-in condition.
- Using an expression which evaluates to true.
- Using static host reservations, a shared network, a subnet, etc.
- Using a hook.
It is envisaged that client classification will be used to change the behavior of almost any part of the DHCP message processing. There are currently five mechanisms that take advantage of client classification: subnet selection, pool selection, definition of DHCPv4 private (codes 224-254) and code 43 options, assignment of different options, and, for DHCPv4 cable modems, the setting of specific options for use with the TFTP server address and the boot file field.
The classification process is conducted in several steps:
- The ALL class is associated with the incoming packet.
- Vendor class options are processed.
- Classes with matching expressions and not marked for later evaluation (“on request” or depending on the KNOWN/UNKNOWN built-in classes) are processed in the order they are defined in the configuration; the boolean expression is evaluated and, if it returns true (“match”), the incoming packet is associated with the class.
- If a private or code 43 DHCPv4 option is received, it is decoded following its client class or global (or, for option 43, last resort) definition.
- When the incoming packet belongs the special class, DROP, it is dropped and an informational message is logged with the packet information.
- A subnet is chosen, possibly based on the class information when some subnets are reserved. More precisely: when choosing a subnet, the server iterates over all of the subnets that are feasible given the information found in the packet (client address, relay address, etc.). It uses the first subnet it finds that either doesn’t have a class associated with it, or has a class which matches one of the packet’s classes.
- The server looks for host reservations. If an identifier from the incoming packet matches a host reservation in the subnet or shared network, the packet is associated with the KNOWN class and all classes of the host reservation. If a reservation is not found, the packet is assigned to the UNKNOWN class.
- Classes with matching expressions - directly, or indirectly using the KNOWN/UNKNOWN built-in classes and not marked for later evaluation (“on request”) - are processed in the order they are defined in the configuration; the boolean expression is evaluated and, if it returns true (“match”), the incoming packet is associated with the class. After a subnet is selected, the server determines whether there is a reservation for a given client. Therefore, it is not possible to use KNOWN/UNKNOWN classes to select a shared network or a subnet, nor to make DROP class dependent of KNOWN/UNKNOWN classes.
- If needed, addresses and prefixes from pools are assigned, possibly based on the class information when some pools are reserved for class members.
- Classes marked as “required” are evaluated in the order in which they are listed: first the shared network, then the subnet, and finally the pools that assigned resources belong to.
- Options are assigned, again possibly based on the class information in the order that classes were associated with the incoming packet. For DHCPv4 private and code 43 options, this includes class local option definitions.
Note
Client classes in Kea follow the order in which they are specified in the configuration (vs. alphabetical order). Required classes follow the order in which they are required.
When determining which options to include in the response, the server examines the union of options from all of the assigned classes. If two or more classes include the same option, the value from the first class examined is used; classes are examined in the order they were associated, so ALL is always the first class and matching required classes are last.
As an example, imagine that an incoming packet matches two classes. Class “foo” defines values for an NTP server (option 42 in DHCPv4) and an SMTP server (option 69 in DHCPv4), while class “bar” defines values for an NTP server and a POP3 server (option 70 in DHCPv4). The server examines the three options - NTP, SMTP, and POP3 - and returns any that the client requested. As the NTP server was defined twice, the server chooses only one of the values for the reply; the class from which the value is obtained determined as explained in the previous paragraph.
Note
Care should be taken with client classification, as it is easy for clients that do not meet any class criteria to be denied service altogether.
14.2. Built-in Client Classes¶
Some classes are built-in, so they do not need to be defined. The main example uses Vendor Class information: the server checks whether an incoming DHCPv4 packet includes the vendor class identifier option (60) or an incoming DHCPv6 packet includes the vendor class option (16). If it does, the content of that option is prepended with “VENDOR_CLASS_” and the result is interpreted as a class. For example, modern cable modems send this option with value “docsis3.0”, so the packet belongs to class “VENDOR_CLASS_docsis3.0”.
The “HA_” prefix is used by the High Availability hooks library to designate certain servers to process DHCP packets as a result of load balancing. The class name is constructed by prepending the “HA_” prefix to the name of the server which should process the DHCP packet. This server uses an appropriate pool or subnet to allocate IP addresses (and/or prefixes), based on the assigned client classes. The details can be found in ha: High Availability.
The BOOTP class is used by the BOOTP hook library to classify and respond to inbound BOOTP queries.
Other examples are the ALL class, which all incoming packets belong to, and the KNOWN class, assigned when host reservations exist for a particular client. By convention, built-in classes’ names begin with all capital letters.
Currently recognized built-in class names are ALL, KNOWN and UNKNOWN, and the prefixes VENDOR_CLASS_, HA_, AFTER_, and EXTERNAL_. Although the AFTER_ prefix is a provision for an as-yet-unwritten hook, the EXTERNAL_ prefix can be freely used; built-in classes are implicitly defined so they never raise warnings if they do not appear in the configuration.
14.3. Using Expressions in Classification¶
The expression portion of a classification definition contains operators and values. All values are currently strings; operators take a string or strings and return another string. When all the operations have completed, the result should be a value of “true” or “false”. The packet belongs to the class (and the class name is added to the list of classes) if the result is “true”. Expressions are written in standard format and can be nested.
Expressions are pre-processed during the parsing of the configuration file and converted to an internal representation. This allows certain types of errors to be caught and logged during parsing. Examples of these errors include an incorrect number or type of argument to an operator. The evaluation code also checks for this class of error and generally throws an exception, though this should not occur in a normally functioning system.
Other issues, such as the starting position of a substring being outside of the substring or an option not existing in the packet, result in the operator returning an empty string.
Dependencies between classes are also checked. For instance, forward dependencies are rejected when the configuration is parsed; an expression can only depend on already-defined classes (including built-in classes) which are evaluated in a previous or the same evaluation phase. This does not apply to the KNOWN or UNKNOWN classes.
Name | Example expression | Example value |
---|---|---|
String literal | ‘example’ | ‘example’ |
Hexadecimal string literal | 0x5a7d | ‘Z}’ |
IP address literal | 10.0.0.1 | 0x0a000001 |
Integer literal | 123 | ‘123’ |
Binary content of the option | option[123].hex | ‘(content of the option)’ |
Option existence | option[123].exists | ‘true’ |
Binary content of the sub-option | option[12].option[34].hex | ‘(content of the sub-option)’ |
Sub-Option existence | option[12].option[34].exists | ‘true’ |
Client class membership | member(‘foobar’) | ‘true’ |
Known client | known | member(‘KNOWN’) |
Unknown client | unknown | not member(‘KNOWN’) |
DHCPv4 relay agent sub-option | relay4[123].hex | ‘(content of the RAI sub-option)’ |
DHCPv6 Relay Options | relay6[nest].option[code].hex | (value of the option) |
DHCPv6 Relay Peer Address | relay6[nest].peeraddr | 2001:DB8::1 |
DHCPv6 Relay Link Address | relay6[nest].linkaddr | 2001:DB8::1 |
Interface name of packet | pkt.iface | eth0 |
Source address of packet | pkt.src | 10.1.2.3 |
Destination address of packet | pkt.dst | 10.1.2.3 |
Length of packet | pkt.len | 513 |
Hardware address in DHCPv4 packet | pkt4.mac | 0x010203040506 |
Hardware length in DHCPv4 packet | pkt4.hlen | 6 |
Hardware type in DHCPv4 packet | pkt4.htype | 6 |
ciaddr field in DHCPv4 packet | pkt4.ciaddr | 192.0.2.1 |
giaddr field in DHCPv4 packet | pkt4.giaddr | 192.0.2.1 |
yiaddr field in DHCPv4 packet | pkt4.yiaddr | 192.0.2.1 |
siaddr field in DHCPv4 packet | pkt4.siaddr | 192.0.2.1 |
Message type in DHCPv4 packet | pkt4.msgtype | 1 |
Transaction ID (xid) in DHCPv4 packet | pkt4.transid | 12345 |
Message type in DHCPv6 packet | pkt6.msgtype | 1 |
Transaction ID in DHCPv6 packet | pkt6.transid | 12345 |
Vendor option existence (any vendor) | vendor[*].exists | true |
Vendor option existence (specific vendor) | vendor[4491].exists | true |
Enterprise-id from vendor option | vendor.enterprise | 4491 |
Vendor sub-option existence | vendor[4491].option[1].exists | true |
Vendor sub-option content | vendor[4491].option[1].hex | docsis3.0 |
Vendor class option existence (any vendor) | vendor-class[*].exist s | true |
Vendor class option existence (specific vendor) | vendor-class[4491].exists | true |
Enterprise-id from vendor class option | vendor-class.enterprise | 4491 |
First data chunk from vendor class option | vendor-class[4491].data | docsis3.0 |
Specific data chunk from vendor class option | vendor-class[4491].data[3] | docsis3.0 |
Notes:
Hexadecimal strings are converted into a string as expected. The starting “0X” or “0x” is removed, and if the string is an odd number of characters a “0” is prepended to it.
IP addresses are converted into strings of length 4 or 16. IPv4, IPv6, and IPv4-embedded IPv6 (e.g. IPv4-mapped IPv6) addresses are supported.
Integers in an expression are converted to 32-bit unsigned integers and are represented as four-byte strings; for example, 123 is represented as 0x0000007b. All expressions that return numeric values use 32-bit unsigned integers, even if the field in the packet is smaller. In general, it is easier to use decimal notation to represent integers, but it is also possible to use hexadecimal notation. When writing an integer in hexadecimal, care should be taken to make sure the value is represented as 32 bits, e.g. use 0x00000001 instead of 0x1 or 0x01. Also, make sure the value is specified in network order, e.g. 1 is represented as 0x00000001.
“option[code].hex” extracts the value of the option with the code “code” from the incoming packet. If the packet doesn’t contain the option, it returns an empty string. The string is presented as a byte string of the option payload, without the type code or length fields.
“option[code].exists” checks whether an option with the code “code” is present in the incoming packet. It can be used with empty options.
“member(‘foobar’)” checks whether the packet belongs to the client class “foobar”. To avoid dependency loops, the configuration file parser verifies whether client classes were already defined or are built-in, i.e., beginning by “VENDOR_CLASS_”, “AFTER_” (for the to-come “after” hook) and “EXTERNAL_” or equal to “ALL”, “KNOWN”, “UNKNOWN”, etc.
“known” and “unknown” are shorthand for “member(‘KNOWN’)” and “not member(‘KNOWN’)”. Note that the evaluation of any expression using directly or indirectly the “KNOWN” class is deferred after the host reservation lookup (i.e. when the “KNOWN” or “UNKNOWN” partition is determined).
“relay4[code].hex” attempts to extract the value of the sub-option “code” from the option inserted as the DHCPv4 Relay Agent Information (82) option. If the packet doesn’t contain a RAI option, or the RAI option doesn’t contain the requested sub-option, the expression returns an empty string. The string is presented as a byte string of the option payload without the type code or length fields. This expression is allowed in DHCPv4 only.
“relay4” shares the same representation types as “option”; for instance, “relay4[code].exists” is supported.
“relay6[nest]” allows access to the encapsulations used by any DHCPv6 relays that forwarded the packet. The “nest” level specifies the relay from which to extract the information, with a value of 0 indicating the relay closest to the DHCPv6 server. Negative values allow specifying relays counted from the DHCPv6 client, -1 indicating the relay closest to the client. In general, negative “nest” level is the same as the number of relays + “nest” level. If the requested encapsulation doesn’t exist, an empty string “” is returned. This expression is allowed in DHCPv6 only.
“relay6[nest].option[code]” shares the same representation types as “option”; for instance, “relay6[nest].option[code].exists” is supported.
Expressions starting with “pkt4” can be used only in DHCPv4. They allow access to DHCPv4 message fields.
“pkt6” refers to information from the client request. To access any information from an intermediate relay use “relay6”. “pkt6.msgtype” and “pkt6.transid” output a 4-byte binary string for the message type or transaction id. For example the message type SOLICIT will be “0x00000001” or simply 1 as in “pkt6.msgtype == 1”.
Vendor option means the Vendor-Identifying Vendor-Specific Information option in DHCPv4 (code 125; see Section 4 of RFC 3925) and Vendor-Specific Information Option in DHCPv6 (code 17, defined in Section 21.17 of RFC 8415). Vendor class option means Vendor-Identifying Vendor Class Option in DHCPv4 (code 124; see Section 3 of RFC 3925) in DHCPv4 and Class Option in DHCPv6 (code 16; see Section 21.16 of RFC 8415). Vendor options may have sub-options that are referenced by their codes. Vendor class options do not have sub-options, but rather data chunks, which are referenced by index value. Index 0 means the first data chunk, index 1 is for the second data chunk (if present), etc.
In the vendor and vendor-class constructs an asterisk (*) or 0 can be used to specify a wildcard enterprise-id value, i.e. it will match any enterprise-id value.
Vendor Class Identifier (option 60 in DHCPv4) can be accessed using the option[60] expression.
RFC 3925 and RFC 8415 allow for multiple instances of vendor options to appear in a single message. The client classification code currently examines the first instance if more than one appear. For the vendor.enterprise and vendor-class.enterprise expressions, the value from the first instance is returned. Please submit a feature request on the Kea GitLab site to request support for multiple instances.
Name | Example | Description |
---|---|---|
Equal | ‘foo’ == ‘bar’ | Compare the two values and return “true” or “false” |
Not | not (‘foo’ == ‘bar’) | Logical negation |
And | (‘foo’ == ‘bar’) and (‘bar’ == ‘foo’) | Logical and |
Or | (‘foo’ == ‘bar’) or (‘bar’ == ‘foo’) | Logical or |
Substring | substring(‘foobar’,0,3) | Return the requested substring |
Concat | concat(‘foo’,’bar’) | Return the concatenation of the strings |
Ifelse | ifelse(‘foo’ == ‘bar’,’us’,’them’) | Return the branch value according to the condition |
Hexstring | hexstring(‘foo’, ‘-‘) | Converts the value to a hexadecimal string, e.g. 0a:1b:2c:3e |
14.3.1. Logical operators¶
The Not, And, and Or logical operators are the common operators. Not has the highest precedence and Or the lowest. And and Or are (left) associative. Parentheses around a logical expression can be used to enforce a specific grouping; for instance, in “A and (B or C)” (without parentheses “A and B or C” means “(A and B) or C”).
14.3.2. Substring¶
The substring operator “substring(value, start, length)” accepts both positive and negative values for the starting position and the length. For “start”, a value of 0 is the first byte in the string while -1 is the last byte. If the starting point is outside of the original string an empty string is returned. “length” is the number of bytes to extract. A negative number means to count towards the beginning of the string but does not include the byte pointed to by “start”. The special value “all” means to return all bytes from start to the end of the string. If the length is longer than the remaining portion of the string, then the entire remaining portion is returned. Some examples may be helpful:
substring('foobar', 0, 6) == 'foobar'
substring('foobar', 3, 3) == 'bar'
substring('foobar', 3, all) == 'bar'
substring('foobar', 1, 4) == 'ooba'
substring('foobar', -5, 4) == 'ooba'
substring('foobar', -1, -3) == 'oba'
substring('foobar', 4, -2) == 'ob'
substring('foobar', 10, 2) == ''
14.3.3. Concat¶
The concat function “concat(string1, string2)” returns the concatenation of its two arguments. For instance:
concat('foo', 'bar') == 'foobar'
14.3.4. Ifelse¶
The ifelse function “ifelse(cond, iftrue, ifelse)” returns the “iftrue” or “ifelse” branch value following the boolean condition “cond”. For instance:
ifelse(option[230].exists, option[230].hex, 'none')
14.3.5. Hexstring¶
The hexstring function “hexstring(binary, separator)” returns the binary value as its hexadecimal string representation: pairs of hexadecimal digits separated by the separator, e.g ‘:’, ‘-‘, ‘’ (empty separator).
hexstring(pkt4.mac, ':')
Note
The expression for each class is executed on each packet received. If the expressions are overly complex, the time taken to execute them may impact the performance of the server. Administrators who need complex or time-consuming expressions should consider writing a hook to perform the necessary work.
14.4. Configuring Classes¶
A class contains five items: a name, a test expression, option data, an option definition, and an only-if-required flag. The name must exist and must be unique among all classes. The test expression, option data and definition, and only-if-required flag are optional.
The test expression is a string containing the logical expression used to determine membership in the class. The entire expression is in double quotes.
The option data is a list which defines any options that should be assigned to members of this class.
The option definition is for DHCPv4 option 43 (DHCPv4 Vendor-Specific Options) and DHCPv4 private options (DHCPv4 Private Options).
Usually the test expression is evaluated before subnet selection, but in some cases it is useful to evaluate it later when the subnet, shared network, or pools are known but output option processing has not yet been done. The only-if-required flag, false by default, allows the evaluation of the test expression only when it is required, i.e. in a require-client-classes list of the selected subnet, shared network, or pool.
The require-client-classes list which is valid for shared-network, subnet, and pool scope specifies the classes which are evaluated in the second pass before output option processing. The list is built in the reversed precedence order of option data, i.e. an option data item in a subnet takes precedence over one in a shared network, but required class in a subnet is added after one in a shared network. The mechanism is related to the only-if-required flag but it is not mandatory that the flag be set to true.
In the following example, the class named “Client_foo” is defined. It is comprised of all clients whose client ids (option 61) start with the string “foo”. Members of this class will be given 192.0.2.1 and 192.0.2.2 as their domain name servers.
"Dhcp4": {
"client-classes": [
{
"name": "Client_foo",
"test": "substring(option[61].hex,0,3) == 'foo'",
"option-data": [
{
"name": "domain-name-servers",
"code": 6,
"space": "dhcp4",
"csv-format": true,
"data": "192.0.2.1, 192.0.2.2"
}
]
},
...
],
...
}
This example shows a client class being defined for use by the DHCPv6 server. In it the class named “Client_enterprise” is defined. It is comprised of all clients whose client identifiers start with the given hex string (which would indicate a DUID based on an enterprise id of 0xAABBCCDD). Members of this class will be given an 2001:db8:0::1 and 2001:db8:2::1 as their domain name servers.
"Dhcp6": {
"client-classes": [
{
"name": "Client_enterprise",
"test": "substring(option[1].hex,0,6) == 0x0002AABBCCDD",
"option-data": [
{
"name": "dns-servers",
"code": 23,
"space": "dhcp6",
"csv-format": true,
"data": "2001:db8:0::1, 2001:db8:2::1"
}
]
},
...
],
...
}
14.5. Using Static Host Reservations In Classification¶
Classes can be statically assigned to the clients using techniques described in Reserving Client Classes in DHCPv4 and Reserving Client Classes in DHCPv6.
14.6. Configuring Subnets With Class Information¶
In certain cases it is beneficial to restrict access to certain subnets only to clients that belong to a given class, using the “client-class” keyword when defining the subnet.
Let’s assume that the server is connected to a network segment that uses the 192.0.2.0/24 prefix. The administrator of that network has decided that addresses from the range 192.0.2.10 to 192.0.2.20 are going to be managed by the DHCP4 server. Only clients belonging to client class Client_foo are allowed to use this subnet. Such a configuration can be achieved in the following way:
"Dhcp4": {
"client-classes": [
{
"name": "Client_foo",
"test": "substring(option[61].hex,0,3) == 'foo'",
"option-data": [
{
"name": "domain-name-servers",
"code": 6,
"space": "dhcp4",
"csv-format": true,
"data": "192.0.2.1, 192.0.2.2"
}
]
},
...
],
"subnet4": [
{
"subnet": "192.0.2.0/24",
"pools": [ { "pool": "192.0.2.10 - 192.0.2.20" } ],
"client-class": "Client_foo"
},
...
],,
...
}
The following example shows how to restrict access to a DHCPv6 subnet. This configuration will restrict use of the addresses 2001:db8:1::1 to 2001:db8:1::FFFF to members of the “Client_enterprise” class.
"Dhcp6": {
"client-classes": [
{
"name": "Client_enterprise",
"test": "substring(option[1].hex,0,6) == 0x0002AABBCCDD",
"option-data": [
{
"name": "dns-servers",
"code": 23,
"space": "dhcp6",
"csv-format": true,
"data": "2001:db8:0::1, 2001:db8:2::1"
}
]
},
...
],
"subnet6": [
{
"subnet": "2001:db8:1::/64",
"pools": [ { "pool": "2001:db8:1::-2001:db8:1::ffff" } ],
"client-class": "Client_enterprise"
}
],
...
}
14.7. Configuring Pools With Class Information¶
Similar to subnets, in certain cases access to certain address or prefix pools must be restricted to only clients that belong to a given class, using the “client-class” when defining the pool.
Let’s assume that the server is connected to a network segment that uses the 192.0.2.0/24 prefix. The administrator of that network has decided that addresses from the range 192.0.2.10 to 192.0.2.20 are going to be managed by the DHCP4 server. Only clients belonging to client class Client_foo are allowed to use this pool. Such a configuration can be achieved in the following way:
"Dhcp4": {
"client-classes": [
{
"name": "Client_foo",
"test": "substring(option[61].hex,0,3) == 'foo'",
"option-data": [
{
"name": "domain-name-servers",
"code": 6,
"space": "dhcp4",
"csv-format": true,
"data": "192.0.2.1, 192.0.2.2"
}
]
},
...
],
"subnet4": [
{
"subnet": "192.0.2.0/24",
"pools": [
{
"pool": "192.0.2.10 - 192.0.2.20",
"client-class": "Client_foo"
}
]
},
...
],,
}
The following example shows how to restrict access to an address pool. This configuration will restrict use of the addresses 2001:db8:1::1 to 2001:db8:1::FFFF to members of the “Client_enterprise” class.
"Dhcp6": {
"client-classes": [
{
"name": "Client_enterprise_",
"test": "substring(option[1].hex,0,6) == 0x0002AABBCCDD",
"option-data": [
{
"name": "dns-servers",
"code": 23,
"space": "dhcp6",
"csv-format": true,
"data": "2001:db8:0::1, 2001:db8:2::1"
}
]
},
...
],
"subnet6": [
{
"subnet": "2001:db8:1::/64",
"pools": [
{
"pool": "2001:db8:1::-2001:db8:1::ffff",
"client-class": "Client_foo"
}
]
},
...
],
...
}
14.8. Using Classes¶
Currently classes can be used for two functions: they can supply options to members of the class, and they can be used to choose a subnet from which an address will be assigned to a class member.
When supplying options, options defined as part of the class definition are considered “class globals.” They will override any global options that may be defined and in turn will be overridden by any options defined for an individual subnet.
14.9. Classes and Hooks¶
Hooks may be used to classify packets. This may be useful if the expression would be complex or time-consuming to write, and could be better or more easily written as code. Once the hook has added the proper class name to the packet, the rest of the classification system will work as expected in choosing a subnet and selecting options. For a description of hooks, see Hooks Libraries; for information on configuring classes, see Configuring Classes and Configuring Subnets With Class Information.
14.10. Debugging Expressions¶
While constructing classification expressions, administrators may find it useful to enable logging; see Logging for a more complete description of the logging facility.
To enable the debug statements in the classification system, the severity must be set to “DEBUG” and the debug level to at least 55. The specific loggers are “kea-dhcp4.eval” and “kea-dhcp6.eval”.
To understand the logging statements, it is essential to understand a bit about how expressions are evaluated; for a more complete description, refer to the design document at https://gitlab.isc.org/isc-projects/kea/wikis/designs/Design-documents. In brief, there are two structures used during the evaluation of an expression: a list of tokens which represent the expressions, and a value stack which represents the values being manipulated.
The list of tokens is created when the configuration file is processed, with most expressions and values being converted to a token. The list is organized in reverse Polish notation. During execution, the list will be traversed in order; as each token is executed it will be able to pop values from the top of the stack and eventually push its result on the top of the stack. Imagine the following expression:
"test": "substring(option[61].hex,0,3) == 'foo'",
This will result in the following tokens:
option, number (0), number (3), substring, text ('foo'), equals
In this example the first three tokens will simply push values onto the stack. The substring token will then remove those three values and compute a result that it places on the stack. The text option also places a value on the stack and finally the equals token removes the two tokens on the stack and places its result on the stack.
When debug logging is enabled, each time a token is evaluated it will emit a log message indicating the values of any objects that were popped off of the value stack and any objects that were pushed onto the value stack.
The values will be displayed as either text, if the command is known to use text values, or hexadecimal, if the command either uses binary values or can manipulate either text or binary values. For expressions that pop multiple values off the stack, the values will be displayed in the order they were popped. For most expressions this will not matter, but for the concat expression the values are displayed in reverse order from their written order in the expression.
Let us assume that the following test has been entered into the configuration. This example skips most of the configuration to concentrate on the test.
"test": "substring(option[61].hex,0,3) == 'foo'",
The logging might then resemble this:
2016-05-19 13:35:04.163 DEBUG [kea.eval/44478] EVAL_DEBUG_OPTION Pushing option 61 with value 0x666F6F626172
2016-05-19 13:35:04.164 DEBUG [kea.eval/44478] EVAL_DEBUG_STRING Pushing text string '0'
2016-05-19 13:35:04.165 DEBUG [kea.eval/44478] EVAL_DEBUG_STRING Pushing text string '3'
2016-05-19 13:35:04.166 DEBUG [kea.eval/44478] EVAL_DEBUG_SUBSTRING Popping length 3, start 0, string 0x666F6F626172 pushing result 0x666F6F
2016-05-19 13:35:04.167 DEBUG [kea.eval/44478] EVAL_DEBUG_STRING Pushing text string 'foo'
2016-05-19 13:35:04.168 DEBUG [kea.eval/44478] EVAL_DEBUG_EQUAL Popping 0x666F6F and 0x666F6F pushing result 'true'
Note
The debug logging may be quite verbose if there are a number of expressions to evaluate; that is intended as an aid in helping create and debug expressions. Administrators should plan to disable debug logging when the expressions are working correctly. Users may also wish to include only one set of expressions at a time in the configuration file while debugging them, to limit the log statements. For example, when adding a new set of expressions, an administrator might find it more convenient to create a configuration file that only includes the new expressions until they are working correctly, and then add the new set to the main configuration file.