Provided by: condor_23.6.2+dfsg-2build1_amd64 
NAME
classads - HTCondor Manual
ClassAds are a flexible mechanism for representing the characteristics and constraints of machines and
jobs in the HTCondor system. ClassAds are used extensively in the HTCondor system to represent jobs,
resources, submitters and other HTCondor daemons. An understanding of this mechanism is required to
harness the full flexibility of the HTCondor system.
A ClassAd is a set of uniquely named expressions. Each named expression is called an attribute. The
following shows ten attributes, a portion of an example ClassAd.
MyType = "Machine"
TargetType = "Job"
Machine = "froth.cs.wisc.edu"
Arch = "INTEL"
OpSys = "LINUX"
Disk = 35882
Memory = 128
KeyboardIdle = 173
LoadAvg = 0.1000
Requirements = TARGET.Owner=="smith" || LoadAvg<=0.3 && KeyboardIdle>15*60
ClassAd expressions look very much like expressions in C, and are composed of literals and attribute
references composed with operators and functions. The difference between ClassAd expressions and C
expressions arise from the fact that ClassAd expressions operate in a much more dynamic environment. For
example, an expression from a machine's ClassAd may refer to an attribute in a job's ClassAd, such as
TARGET.Owner in the above example. The value and type of the attribute is not known until the expression
is evaluated in an environment which pairs a specific job ClassAd with the machine ClassAd.
ClassAd expressions handle these uncertainties by defining all operators to be total operators, which
means that they have well defined behavior regardless of supplied operands. This functionality is
provided through two distinguished values, UNDEFINED and ERROR, and defining all operators so that they
can operate on all possible values in the ClassAd system. For example, the multiplication operator which
usually only operates on numbers, has a well defined behavior if supplied with values which are not
meaningful to multiply. Thus, the expression 10 * "A string" evaluates to the value ERROR. Most operators
are strict with respect to ERROR, which means that they evaluate to ERROR if any of their operands are
ERROR. Similarly, most operators are strict with respect to UNDEFINED.
CLASSADS: OLD AND NEW
ClassAds have existed for quite some time in two forms: Old and New. Old ClassAds were the original form
and were used in HTCondor until HTCondor version 7.5.0. They were heavily tied to the HTCondor
development libraries. New ClassAds added new features and were designed as a stand-alone library that
could be used apart from HTCondor.
In HTCondor version 7.5.1, HTCondor switched to using the New ClassAd library for all use of ClassAds
within HTCondor. The library is placed into a compatibility mode so that HTCondor 7.5.1 is still able to
exchange ClassAds with older versions of HTCondor.
All user interaction with tools (such as condor_q) as well as output of tools is still compatible with
Old ClassAds. Before HTCondor version 7.5.1, New ClassAds were used only in the Job Router. There are
some syntax and behavior differences between Old and New ClassAds, all of which should remain invisible
to users of HTCondor.
A complete description of New ClassAds can be found at http://htcondor.org/classad/classad.html, and in
the ClassAd Language Reference Manual found on that web page.
Some of the features of New ClassAds that are not in Old ClassAds are lists, nested ClassAds, time
values, and matching groups of ClassAds. HTCondor has avoided using these features, as using them makes
it difficult to interact with older versions of HTCondor. But, users can start using them if they do not
need to interact with versions of HTCondor older than 7.5.1.
The syntax varies slightly between Old and New ClassAds. Here is an example ClassAd presented in both
forms. The Old form:
Foo = 3
Bar = "ab\"cd\ef"
Moo = Foo =!= Undefined
The New form:
[
Foo = 3;
Bar = "ab\"cd\\ef";
Moo = Foo isnt Undefined;
]
HTCondor will convert to and from Old ClassAd syntax as needed.
New ClassAd Attribute References
Expressions often refer to ClassAd attributes. These attribute references work differently in Old
ClassAds as compared with New ClassAds. In New ClassAds, an unscoped reference is looked for only in the
local ClassAd. An unscoped reference is an attribute that does not have a MY. or TARGET. prefix. The
local ClassAd may be described by an example. Matchmaking uses two ClassAds: the job ClassAd and the
machine ClassAd. The job ClassAd is evaluated to see if it is a match for the machine ClassAd. The job
ClassAd is the local ClassAd. Therefore, in the Requirements attribute of the job ClassAd, any attribute
without the prefix TARGET. is looked up only in the job ClassAd. With New ClassAd evaluation, the use of
the prefix MY. is eliminated, as an unscoped reference can only refer to the local ClassAd.
The MY. and TARGET. scoping prefixes only apply when evaluating an expression within the context of two
ClassAds. Two examples that exemplify this are matchmaking and machine policy evaluation. When evaluating
an expression within the context of a single ClassAd, MY. and TARGET. are not defined. Using them within
the context of a single ClassAd will result in a value of Undefined. Two examples that exemplify
evaluating an expression within the context of a single ClassAd are during user job policy evaluation,
and with the -constraint option to command-line tools.
New ClassAds have no CurrentTime attribute. If needed, use the time() function instead. In order to mimic
Old ClassAd semantics in current versions of HTCondor, all ClassAds have an implicit CurrentTime
attribute, with a value of time().
In current versions of HTCondor, New ClassAds will mimic the evaluation behavior of Old ClassAds. No
configuration variables or submit description file contents should need to be changed. To eliminate this
behavior and use only the semantics of New ClassAds, set the configuration variable
STRICT_CLASSAD_EVALUATION to True. This permits testing expressions to see if any adjustment is required,
before a future version of HTCondor potentially makes New ClassAds evaluation behavior the default or the
only option.
CLASSAD SYNTAX
ClassAd expressions are formed by composing literals, attribute references and other sub-expressions with
operators and functions.
Composing Literals
Literals in the ClassAd language may be of integer, real, string, undefined or error types. The syntax of
these literals is as follows:
Integer
A sequence of continuous digits (i.e., [0-9]). Additionally, the keywords TRUE and FALSE (case
insensitive) are syntactic representations of the integers 1 and 0 respectively.
Real Two sequences of continuous digits separated by a period (i.e., [0-9]+.[0-9]+).
String A double quote character, followed by a list of characters terminated by a double quote
character. A backslash character inside the string causes the following character to be
considered as part of the string, irrespective of what that character is.
Undefined
The keyword UNDEFINED (case insensitive) represents the UNDEFINED value.
Error The keyword ERROR (case insensitive) represents the ERROR value.
Attributes
Every expression in a ClassAd is named by an attribute name. Together, the (name,expression) pair is
called an attribute. An attribute may be referred to in other expressions through its attribute name.
Attribute names are sequences of alphabetic characters, digits and underscores, and may not begin with a
digit. All characters in the name are significant, but case is not significant. Thus, Memory, memory and
MeMoRy all refer to the same attribute.
An attribute reference consists of the name of the attribute being referenced, and an optional scope
resolution prefix. The prefixes that may be used are MY. and TARGET.. The case used for these prefixes is
not significant. The semantics of supplying a prefix are discussed in classads/classad-mechanism:classad
evaluation semantics.
Expression Operators
The operators that may be used in ClassAd expressions are similar to those available in C. The available
operators and their relative precedence is shown in the following example:
- (unary negation) (high precedence)
* / %
+ - (addition, subtraction)
< <= >= >
== != =?= is =!= isnt
&&
|| (low precedence)
The operator with the highest precedence is the unary minus operator. The only operators which are
unfamiliar are the =?=, is, =!= and isnt operators, which are discussed in
classads/classad-mechanism:classad evaluation semantics.
Predefined Functions
Any ClassAd expression may utilize predefined functions. Function names are case insensitive. Parameters
to functions and a return value from a function may be typed (as given) or not. Nested or recursive
function calls are allowed.
Here are descriptions of each of these predefined functions. The possible types are the same as itemized
in classads/classad-mechanism:classad syntax. Where the type may be any of these literal types, it is
called out as AnyType. Where the type is Integer, but only returns the value 1 or 0 (implying True or
False), it is called out as Boolean. The format of each function is given as
ReturnType FunctionName(ParameterType parameter1, ParameterType parameter2, ...)
Optional parameters are given within square brackets.
AnyType eval(AnyType Expr)
Evaluates Expr as a string and then returns the result of evaluating the contents of the string as
a ClassAd expression. This is useful when referring to an attribute such as slotX_State where X,
the desired slot number is an expression, such as SlotID+10. In such a case, if attribute SlotID
is 5, the value of the attribute slot15_State can be referenced using the expression
eval(strcat("slot", SlotID+10,"_State")). Function strcat() calls function string() on the second
parameter, which evaluates the expression, and then converts the integer result 15 to the string
"15". The concatenated string returned by strcat() is "slot15_State", and this string is then
evaluated.
Note that referring to attributes of a job from within the string passed to eval() in the
Requirements or Rank expressions could cause inaccuracies in HTCondor's automatic auto-clustering
of jobs into equivalent groups for matchmaking purposes. This is because HTCondor needs to
determine which ClassAd attributes are significant for matchmaking purposes, and indirect
references from within the string passed to eval() will not be counted.
String unparse(Attribute attr)
This function looks up the value of the provided attribute and returns the unparsed version as a
string. The attribute's value is not evaluated. If the attribute's value is x + 3, then the
function would return the string "x + 3". If the provided attribute cannot be found, an empty
string is returned.
This function returns ERROR if other than exactly 1 argument is given or the argument is not an
attribute reference.
String unresolved(Attribute attr)
This function returns the external attribute references and unresolved attribute references of the
expression that is the value of the provided attribute. If the provided attribute cannot be
found, then undefined is returned.
For example, in a typical job ClassAd if the Requirements expression has the value OpSys ==
"LINUX" && TARGET.Arch == "ARM" && Cpus >= RequestCpus, then unresolved(Requirements) will return
"Arch,Cpus,OpSys" because those will not be attributes of the job ClassAd.
Boolean unresolved(Attribute attr, String pattern)
This function returns True when at least one of the external or unresolved attribute references of
the expression that is the value of the provided attribute matches the given Perl regular
expression pattern. If none of the references match the pattern, then False is returned. If the
provided attribute cannot be found, then undefined is returned.
For example, in a typical job ClassAd if the Requirements expression has the value OpSys ==
"LINUX" && Arch == "ARM", then unresolved(Requirements, "^OpSys") will return True, and
unresolved(Requirements, "OpSys.+") will return False.
The intended use of this function is to make it easier to apply a submit transform to a job only
when the job does not already reference a certain attribute. For instance
JOB_TRANSFORM_DefPlatform @=end
# Apply this transform only when the job requirements does not reference OpSysAndver or OpSysName
REQUIREMENTS ! unresolved(Requirements, "OpSys.+")
# Add a clause to the job requirements to match only CentOs7 machines
SET Requirements $(MY.Requirements) && OpSysAndVer == "CentOS7"
@end
AnyType ifThenElse(AnyType IfExpr,AnyType ThenExpr, AnyType ElseExpr)
A conditional expression is described by IfExpr. The following defines return values, when IfExpr
evaluates to
• True. Evaluate and return the value as given by ThenExpr.
• False. Evaluate and return the value as given by ElseExpr.
• UNDEFINED. Return the value UNDEFINED.
• ERROR. Return the value ERROR.
• 0.0. Evaluate, and return the value as given by ElseExpr.
• non-0.0 Real values. Evaluate, and return the value as given by ThenExpr.
Where IfExpr evaluates to give a value of type String, the function returns the value ERROR. The
implementation uses lazy evaluation, so expressions are only evaluated as defined.
This function returns ERROR if other than exactly 3 arguments are given.
Boolean isUndefined(AnyType Expr)
Returns True, if Expr evaluates to UNDEFINED. Returns False in all other cases.
This function returns ERROR if other than exactly 1 argument is given.
Boolean isError(AnyType Expr)
Returns True, if Expr evaluates to ERROR. Returns False in all other cases.
This function returns ERROR if other than exactly 1 argument is given.
Boolean isString(AnyType Expr)
Returns True, if the evaluation of Expr gives a value of type String. Returns False in all other
cases.
This function returns ERROR if other than exactly 1 argument is given.
Boolean isInteger(AnyType Expr)
Returns True, if the evaluation of Expr gives a value of type Integer. Returns False in all other
cases.
This function returns ERROR if other than exactly 1 argument is given.
Boolean isReal(AnyType Expr)
Returns True, if the evaluation of Expr gives a value of type Real. Returns False in all other
cases.
This function returns ERROR if other than exactly 1 argument is given.
Boolean isList(AnyType Expr)
Returns True, if the evaluation of Expr gives a value of type List. Returns False in all other
cases.
This function returns ERROR if other than exactly 1 argument is given.
Boolean isClassAd(AnyType Expr)
Returns True, if the evaluation of Expr gives a value of type ClassAd. Returns False in all other
cases.
This function returns ERROR if other than exactly 1 argument is given.
Boolean isBoolean(AnyType Expr)
Returns True, if the evaluation of Expr gives the integer value 0 or 1. Returns False in all other
cases.
This function returns ERROR if other than exactly 1 argument is given.
Boolean isAbstime(AnyType Expr)
Returns True, if the evaluation of Expr returns an abstime type. Returns False in all other cases.
This function returns ERROR if other than exactly 1 argument is given.
Boolean isReltime(AnyType Expr)
Returns True, if the evaluation of Expr returns an relative time type. Returns False in all other
cases.
This function returns ERROR if other than exactly 1 argument is given.
Boolean member(AnyType m, ListType l)
Returns error if m does not evalute to a scalar, or l does not evaluate to a list. Otherwise the
elements of l are evaluted in order, and if an element is equal to m in the sense of == the result
of the function is True. Otherwise the function returns false.
Boolean anyCompare(string op, list l, AnyType t)
Returns error if op does not evalute to one of <, <=, ==, >, >=, !-, is or isnt. Returns error if
l isn't a list, or t isn't a scalar Otherwise the elements of l are evaluted and compared to t
using the corresponding operator defined by op. If any of the members of l evaluate to true, the
result is True. Otherwise the function returns False.
Boolean allCompare(string op, list l, AnyType t)
Returns error if op does not evalute to one of <, <=, ==, >, >=, !-, is or isnt. Returns error if
l isn't a list, or t isn't a scalar Otherwise the elements of l are evaluted and compared to t
using the corresponding operator defined by op. If all of the members of l evaluate to true, the
result is True. Otherwise the function returns False.
Boolean identicalMember(AnyType m, ListType l)
Returns error if m does not evalute to a scalar, or l does not evaluate to a list. Otherwise the
elements of l are evaluted in order, and if an element is equal to m in the sense of =?= the
result of the function is True. Otherwise the function returns false.
Integer int(AnyType Expr)
Returns the integer value as defined by Expr. Where the type of the evaluated Expr is Real, the
value is truncated (round towards zero) to an integer. Where the type of the evaluated Expr is
String, the string is converted to an integer using a C-like atoi() function. When this result is
not an integer, ERROR is returned. Where the evaluated Expr is ERROR or UNDEFINED, ERROR is
returned.
This function returns ERROR if other than exactly 1 argument is given.
Real real(AnyType Expr)
Returns the real value as defined by Expr. Where the type of the evaluated Expr is Integer, the
return value is the converted integer. Where the type of the evaluated Expr is String, the string
is converted to a real value using a C-like atof() function. When this result is not a real,
ERROR is returned. Where the evaluated Expr is ERROR or UNDEFINED, ERROR is returned.
This function returns ERROR if other than exactly 1 argument is given.
String string(AnyType Expr)
Returns the string that results from the evaluation of Expr. Converts a non-string value to a
string. Where the evaluated Expr is ERROR or UNDEFINED, ERROR is returned.
This function returns ERROR if other than exactly 1 argument is given.
Bool bool(AnyType Expr)
Returns the boolean that results from the evaluation of Expr. Converts a non-boolean value to a
bool. A string expression that evaluates to the string "true" yields true, and "false" returns
This function returns ERROR if other than exactly 1 argument is given.
AbsTime absTime(AnyType t [, int z])
Creates an AbsTime value corresponding to time t an time-zone offset z. If t is a String, then z
must be omitted, and t is parsed as a specification as follows.
The operand t is parsed as a specification of an instant in time (date and time). This function
accepts the canonical native representation of AbsTime values, but minor variations in format are
allowed. The default format is yyyy-mm-ddThh:mm:sszzzzz where zzzzz is a time zone in the format
+hh:mm or -hh:mm
If t and z are both omitted, the result is an AbsTime value representing the time and place where
the function call is evaluated. Otherwise, t is converted to a Real by the function “real”, and
treated as a number of seconds from the epoch, Midnight January 1, 1970 UTC. If z is specified, it
is treated as a number of seconds east of Greenwich. Otherwise, the offset is calculated from t
according to the local rules for the place where the function is evaluated.
RelTime relTime(AnyType t)
If the operand t is a String, it is parsed as a specification of a time interval. This function
accepts the canonical native representation of RelTime values, but minor variations in format are
allowed.
Otherwise, t is converted to a Real by the function real, and treated as a number of seconds. The
default string format is [-]days+hh:mm:ss.fff, where leading components and the fraction .fff are
omitted if they are zero. In the default syntax, days is a sequence of digits starting with a
non-zero digit, hh, mm, and ss are strings of exactly two digits (padded on the left with zeros if
necessary) with values less than 24, 60, and 60, respectively and fff is a string of exactly three
digits.
Integer floor(AnyType Expr)
Returns the integer that results from the evaluation of Expr, where the type of the evaluated Expr
is Integer. Where the type of the evaluated Expr is not Integer, function real(Expr) is called.
Its return value is then used to return the largest magnitude integer that is not larger than the
returned value. Where real(Expr) returns ERROR or UNDEFINED, ERROR is returned.
This function returns ERROR if other than exactly 1 argument is given.
Integer ceiling(AnyType Expr)
Returns the integer that results from the evaluation of Expr, where the type of the evaluated Expr
is Integer. Where the type of the evaluated Expr is not Integer, function real(Expr) is called.
Its return value is then used to return the smallest magnitude integer that is not less than the
returned value. Where real(Expr) returns ERROR or UNDEFINED, ERROR is returned.
This function returns ERROR if other than exactly 1 argument is given.
Integer pow(Integer base, Integer exponent) OR Real pow(Integer base, Integer exponent) OR Real pow(Real
base, Real exponent)
Calculates base raised to the power of exponent. If exponent is an integer value greater than or
equal to 0, and base is an integer, then an integer value is returned. If exponent is an integer
value less than 0, or if either base or exponent is a real, then a real value is returned. An
invocation with exponent=0 or exponent=0.0, for any value of base, including 0 or 0.0, returns the
value 1 or 1.0, type appropriate.
Integer quantize(AnyType a, Integer b) OR Real quantize(AnyType a, Real b) OR AnyType quantize(AnyType a,
AnyType list b)
quantize() computes the quotient of a/b, in order to further compute `` ceiling(quotient) * b``.
This computes and returns an integral multiple of b that is at least as large as a. So, when b >=
a, the return value will be b. The return type is the same as that of b, where b is an Integer or
Real.
When b is a list, quantize() returns the first value in the list that is greater than or equal to
a. When no value in the list is greater than or equal to a, this computes and returns an integral
multiple of the last member in the list that is at least as large as a.
This function returns ERROR if a or b, or a member of the list that must be considered is not an
Integer or Real.
Here are examples:
8 = quantize(3, 8)
4 = quantize(3, 2)
0 = quantize(0, 4)
6.8 = quantize(1.5, 6.8)
7.2 = quantize(6.8, 1.2)
10.2 = quantize(10, 5.1)
4 = quantize(0, {4})
2 = quantize(2, {1, 2, "A"})
3.0 = quantize(3, {1, 2, 0.5})
3.0 = quantize(2.7, {1, 2, 0.5})
ERROR = quantize(3, {1, 2, "A"})
Integer round(AnyType Expr)
Returns the integer that results from the evaluation of Expr, where the type of the evaluated Expr
is Integer. Where the type of the evaluated Expr is not Integer, function real(Expr) is called.
Its return value is then used to return the integer that results from a round-to-nearest rounding
method. The nearest integer value to the return value is returned, except in the case of the
value at the exact midpoint between two integer values. In this case, the even valued integer is
returned. Where real(Expr) returns ERROR or UNDEFINED, or the integer value does not fit into 32
bits, ERROR is returned.
This function returns ERROR if other than exactly 1 argument is given.
Integer random([ AnyType Expr ])
Where the optional argument Expr evaluates to type Integer or type Real (and called x), the return
value is the integer or real r randomly chosen from the interval 0 <= r < x. With no argument, the
return value is chosen with random(1.0). Returns ERROR in all other cases.
This function returns ERROR if greater than 1 argument is given.
Number sum([ List l ])
The elements of l are evaluated, producing a list l of values. Undefined values are removed. If
the resulting l is composed only of numbers, the result is the sum of the values, as a Real if any
value is Real, and as an Integer otherwise. If the list is empty, the result is 0. If the list has
only Undefined values, the result is UNDEFINED. In other cases, the result is ERROR.
This function returns ERROR if greater than 1 argument is given.
Number avg([ List l ])
The elements of l are evaluated, producing a list l of values. Undefined values are removed. If
the resulting l is composed only of numbers, the result is the average of the values, as a Real.
If the list is empty, the result is 0. If the list has only Undefined values, the result is
UNDEFINED. In other cases, the result is ERROR.
Number min([ List l ])
The elements of l are evaluated, producing a list l of values. Undefined values are removed. If
the resulting l is composed only of numbers, the result is the minimum of the values, as a Real if
any value is Real, and as an Integer otherwise. If the list is empty, the result is UNDEFINED. In
other cases, the result is ERROR.
Number max([ List l ])
The elements of l are evaluated, producing a list l of values. Undefined values are removed. If
the resulting l is composed only of numbers, the result is the maximum of the values, as a Real if
any value is Real, and as an Integer otherwise. If the list is empty, the result is UNDEFINED. In
other cases, the result is ERROR.
String strcat(AnyType Expr1 [ , AnyType Expr2 ...])
Returns the string which is the concatenation of all arguments, where all arguments are converted
to type String by function string(Expr). Returns ERROR if any argument evaluates to UNDEFINED or
ERROR.
String join(String sep, AnyType Expr1 [ , AnyType Expr2 ...]) OR String join(String sep, List list OR
String join(List list
Returns the string which is the concatenation of all arguments after the first one. The first
argument is the separator, and it is inserted between each of the other arguments during
concatenation. All arguments which are not undefined are converted to type String by function
string(Expr) before concatenation. Undefined arguments are skipped. When there are exactly two
arguments, If the second argument is a List, all members of the list are converted to strings and
then joined using the separator. When there is only one argument, and the argument is a List, all
members of the list are converted to strings and then concatenated.
Returns ERROR if any argument evaluates to UNDEFINED or ERROR.
For example:
"a, b, c" = join(", ", "a", "b", "c")
"abc" = join(split("a b c"))
"a;b;c" = join(";", split("a b c"))
String substr(String s, Integer offset [ , Integer length ])
Returns the substring of s, from the position indicated by offset, with (optional) length
characters. The first character within s is at offset 0. If the optional length argument is not
present, the substring extends to the end of the string. If offset is negative, the value (length
- offset) is used for the offset. If length is negative, an initial substring is computed, from
the offset to the end of the string. Then, the absolute value of length characters are deleted
from the right end of the initial substring. Further, where characters of this resulting substring
lie outside the original string, the part that lies within the original string is returned. If the
substring lies completely outside of the original string, the null string is returned.
This function returns ERROR if greater than 3 or less than 2 arguments are given.
Integer strcmp(AnyType Expr1, AnyType Expr2)
Both arguments are converted to type String by function string(Expr). The return value is an
integer that will be
• less than 0, if Expr1 is lexicographically less than Expr2
• equal to 0, if Expr1 is lexicographically equal to Expr2
• greater than 0, if Expr1 is lexicographically greater than Expr2
Case is significant in the comparison. Where either argument evaluates to ERROR or UNDEFINED,
ERROR is returned.
This function returns ERROR if other than 2 arguments are given.
Integer stricmp(AnyType Expr1, AnyType Expr2)
This function is the same as strcmp, except that letter case is not significant.
Integer versioncmp(String left, String right)
This function version-compares two strings. It returns an integer
• less than zero if left is an earlier version than right
• zero if the strings are identical
• more than zero if left is a later version than right.
A version comparison is a lexicographic comparison unless the first difference between the two
strings occurs in a string of digits, in which case, sort by the value of that number (assuming
that more leading zeroes mean smaller numbers). Thus 7.x is earlier than 7.y, 7.9 is earlier than
7.10, and the following sequence is in order: 000, 00, 01, 010, 09, 0, 1, 9, 10.
Boolean versionGT(String left, String right) Boolean versionLT(String left, String right) Boolean
versionGE(String left, String right) Boolean versionLE(String left, String right) Boolean
versionEQ(String left, String right)
As versioncmp() (above), but for a specific comparison and returning a boolean. The two letter codes
stand for "Greater Than", "Less Than", "Greater than or Equal", "Less than or Equal", and "EQual",
respectively.
Boolean version_in_range(String version, String min, String max)
Equivalent to versionLE(min, version) && versionLE(version, max).
String toUpper(AnyType Expr)
The single argument is converted to type String by function string(Expr). The return value is this
string, with all lower case letters converted to upper case. If the argument evaluates to ERROR or
UNDEFINED, ERROR is returned.
This function returns ERROR if other than exactly 1 argument is given.
String toLower(AnyType Expr)
The single argument is converted to type String by function string(Expr). The return value is this
string, with all upper case letters converted to lower case. If the argument evaluates to ERROR or
UNDEFINED, ERROR is returned.
This function returns ERROR if other than exactly 1 argument is given.
Integer size(AnyType Expr)
If Expr evaluates to a string, return the number of characters in the string. If Expr evaluate to
a list, return the number of elements in the list. If Expr evaluate to a classad, return the
number of entries in the ad. Otherwise, ERROR is returned.
List split(String s [ , String tokens ] )
Returns a list of the substrings of s that have been split up by using any of the characters
within string tokens. If tokens is not specified, then all white space characters are used to
delimit the string.
List splitUserName(String Name)
Returns a list of two strings. Where Name includes an @ character, the first string in the list
will be the substring that comes before the @ character, and the second string in the list will be
the substring that comes after. Thus, if Name is "user@domain", then the returned list will be
{"user", "domain"}. If there is no @ character in Name, then the first string in the list will be
Name, and the second string in the list will be the empty string. Thus, if Name is "username",
then the returned list will be {"username", ""}.
List splitSlotName(String Name)
Returns a list of two strings. Where Name includes an @ character, the first string in the list
will be the substring that comes before the @ character, and the second string in the list will be
the substring that comes after. Thus, if Name is "slot1@machine", then the returned list will be
{"slot1", "machine"}. If there is no @ character in Name, then the first string in the list will
be the empty string, and the second string in the list will be Name, Thus, if Name is
"machinename", then the returned list will be {"", "machinename"}.
Integer time()
Returns the current coordinated universal time. This is the time, in seconds, since midnight of
January 1, 1970.
String formatTime([ Integer time ] [ , String format ])
Returns a formatted string that is a representation of time. The argument time is interpreted as
coordinated universal time in seconds, since midnight of January 1, 1970. If not specified, time
will default to the current time.
The argument format is interpreted similarly to the format argument of the ANSI C strftime
function. It consists of arbitrary text plus placeholders for elements of the time. These
placeholders are percent signs (%) followed by a single letter. To have a percent sign in the
output, use a double percent sign (%%). If format is not specified, it defaults to %c.
Because the implementation uses strftime() to implement this, and some versions implement extra,
non-ANSI C options, the exact options available to an implementation may vary. An implementation
is only required to implement the ANSI C options, which are:
%a abbreviated weekday name
%A full weekday name
%b abbreviated month name
%B full month name
%c local date and time representation
%d day of the month (01-31)
%H hour in the 24-hour clock (0-23)
%I hour in the 12-hour clock (01-12)
%j day of the year (001-366)
%m month (01-12)
%M minute (00-59)
%p local equivalent of AM or PM
%S second (00-59)
%U week number of the year (Sunday as first day of week) (00-53)
%w weekday (0-6, Sunday is 0)
%W week number of the year (Monday as first day of week) (00-53)
%x local date representation
%X local time representation
%y year without century (00-99)
%Y year with century
%Z time zone name, if any
String interval(Integer seconds)
Uses seconds to return a string of the form days+hh:mm:ss. This represents an interval of time.
Leading values that are zero are omitted from the string. For example, seconds of 67 becomes
"1:07". A second example, seconds of 1472523 = 17*24*60*60 + 1*60*60 + 2*60 + 3, results in the
string "17+1:02:03".
String evalInEachContext(Expression expr, List contexts)
This function evaluates its first argument as an expression in the context of each Classad in the
second argument and returns a list that is the result of each evaluation. The first argument
should be an expression. If the second argument does not evaluate to a list of ClassAds, ERROR is
returned.
For example:
{true, false} = evalInEachContext(Prio > 2, { [Prio=3;], [Prio=1;] })
{3, 1} = evalInEachContext(Prio, { [Prio=3;], [Prio=1;] })
ERROR = evalInEachContext(Prio > 2, { [Prio=3;], UNDEFINED })
ERROR = evalInEachContext(Prio > 2, UNDEFINED)
String countMatches(Expression expr, List contexts)
This function evaluates its first argument as an expression in the context of each Classad in the
second argument and returns a count of the results that evaluated to True. The first argument
should be an expression. The second argument should be a list of ClassAds or a list of attribute
references to classAds, or should evaluate to a list of ClassAds. This function will always
return a integer value when the first argument is defined and the second argument is not ERROR.
For example:
1 = countMatches(Prio > 2, { [Prio=3;], [Prio=1;] })
1 = countMatches(Prio > 2, { [Prio=3;], UNDEFINED })
0 = countMatches(Prio > 2, UNDEFINED)
AnyType debug(AnyType expression)
This function evaluates its argument, and it returns the result. Thus, it is a no-operation.
However, a side-effect of the function is that information about the evaluation is logged to the
evaluating program's log file, at the D_FULLDEBUG debug level. This is useful for determining why
a given ClassAd expression is evaluating the way it does. For example, if a condor_startd START
expression is unexpectedly evaluating to UNDEFINED, then wrapping the expression in this debug()
function will log information about each component of the expression to the log file, making it
easier to understand the expression.
String envV1ToV2(String old_env)
This function converts a set of environment variables from the old HTCondor syntax to the new
syntax. The single argument should evaluate to a string that represents a set of environment
variables using the old HTCondor syntax (usually stored in the job ClassAd attribute Env). The
result is the same set of environment variables using the new HTCondor syntax (usually stored in
the job ClassAd attribute Environment). If the argument evaluates to UNDEFINED, then the result is
also UNDEFINED.
String mergeEnvironment(String env1 [ , String env2, ... ])
This function merges multiple sets of environment variables into a single set. If multiple
arguments include the same variable, the one that appears last in the argument list is used. Each
argument should evaluate to a string which represents a set of environment variables using the new
HTCondor syntax or UNDEFINED, which is treated like an empty string. The result is a string that
represents the merged set of environment variables using the new HTCondor syntax (suitable for use
as the value of the job ClassAd attribute Environment).
For the following functions, a delimiter is represented by a string. Each character within the delimiter
string delimits individual strings within a list of strings that is given by a single string. The default
delimiter contains the comma and space characters. A string within the list is ended (delimited) by one
or more characters within the delimiter string.
Integer stringListSize(String list [ , String delimiter ])
Returns the number of elements in the string list, as delimited by the optional delimiter string.
Returns ERROR if either argument is not a string.
This function returns ERROR if other than 1 or 2 arguments are given.
Integer stringListSum(String list [ , String delimiter ]) OR Real stringListSum(String list [ , String
delimiter ])
Sums and returns the sum of all items in the string list, as delimited by the optional delimiter
string. If all items in the list are integers, the return value is also an integer. If any item in
the list is a real value (noninteger), the return value is a real. If any item does not represent
an integer or real value, the return value is ERROR.
Real stringListAvg(String list [ , String delimiter ])
Sums and returns the real-valued average of all items in the string list, as delimited by the
optional delimiter string. If any item does not represent an integer or real value, the return
value is ERROR. A list with 0 items (the empty list) returns the value 0.0.
Integer stringListMin(String list [ , String delimiter ]) OR Real stringListMin(String list [ , String
delimiter ])
Finds and returns the minimum value from all items in the string list, as delimited by the
optional delimiter string. If all items in the list are integers, the return value is also an
integer. If any item in the list is a real value (noninteger), the return value is a real. If any
item does not represent an integer or real value, the return value is ERROR. A list with 0 items
(the empty list) returns the value UNDEFINED.
Integer stringListMax(String list [ , String delimiter ]) OR Real stringListMax(String list [ , String
delimiter ])
Finds and returns the maximum value from all items in the string list, as delimited by the
optional delimiter string. If all items in the list are integers, the return value is also an
integer. If any item in the list is a real value (noninteger), the return value is a real. If any
item does not represent an integer or real value, the return value is ERROR. A list with 0 items
(the empty list) returns the value UNDEFINED.
Boolean stringListMember(String x, String list [ , String delimiter ])
Returns TRUE if item x is in the string list, as delimited by the optional delimiter string.
Returns FALSE if item x is not in the string list. Comparison is done with strcmp(). The return
value is ERROR, if any of the arguments are not strings.
Boolean stringListIMember(String x, String list [ , String delimiter ])
Same as stringListMember(), but comparison is done with stricmp(), so letter case is not relevant.
Integer stringListsIntersect(String list1, String list2 [ , String delimiter ])
Returns TRUE if the lists contain any matching elements, and returns FALSE if the lists do not
contain any matching elements. Returns ERROR if either argument is not a string or if an
incorrect number of arguments are given.
Boolean stringListSubsetMatch(String list1, String list2 [ , String delimiter ])
Returns TRUE if all item in the string list1 are also in the string list2, as delimited by the
optional delimiter string. Returns FALSE if list1 has any items that are not in list2. Both lists
are treated as sets. Empty items and duplicate items are ignored. The return value is TRUE if
list1 is UNDEFINED or empty and list2 is any string value. The return value is FALSE if list1 is
any string value and list2 is UNDEFINED. The return value is UNDEFINED if both list1 and list2
are UNDEFINED. The return value is ERROR, if any of the arguments are not either strings or
UNDEFINED
Boolean stringListISubsetMatch(String list1, String list2 [ , String delimiter ])
Same as stringListSubsetMatch(), but the sets are case-insensitive.
The following six functions utilize regular expressions as defined and supported by the PCRE library. See
http://www.pcre.org for complete documentation of regular expressions.
The options argument to these functions is a string of special characters that modify the use of the
regular expressions. Inclusion of characters other than these as options are ignored.
I or i Ignore letter case.
M or m Modifies the interpretation of the caret (^) and dollar sign ($) characters. The caret character
matches the start of a string, as well as after each newline character. The dollar sign character
matches before a newline character.
S or s The period matches any character, including the newline character.
F or f When doing substitution, return the full target string with substitutions applied. Normally, only
the substitute text is returned.
G or g When doing substitution, apply the substitution for every matching portion of the target string
(that doesn't overlap a previous match).
Boolean regexp(String pattern, String target [ , String options ])
Uses the regular expression given by string pattern to scan through the string target. Returns
TRUE when target matches the regular expression given by pattern. Returns FALSE otherwise. If any
argument is not a string, or if pattern does not describe a valid regular expression, returns
ERROR.
Boolean regexpMember(String pattern, List targetStrings [ , String options ])
Uses the description of a regular expression given by string pattern to scan through a List of
string n targetStrings. Returns TRUE when target matches a regular expression given by pattern. If
no strings match, and at least one item in targetString evaluated to undefined, returns undefined.
If any item in targetString before a match evaluated to neither a string nor undefined, returns
ERROR.
String regexps
(String pattern, String target, String substitute [ , String options ]) Uses the regular
expression given by string pattern to scan through the string target. When target matches the
regular expression given by pattern, the string substitute is returned, with backslash expansion
performed. If any argument is not a string, returns ERROR.
String replace
(String pattern, String target, String substitute [ , String options ]) Uses the regular
expression given by string pattern to scan through the string target. Returns a modified version
of target, where the first substring that matches pattern is replaced by the string substitute,
with backslash expansion performed. Equivalent to regexps() with the f option. If any argument is
not a string, returns ERROR.
String replaceall
(String pattern, String target, String substitute [ , String options ]) Uses the regular
expression given by string pattern to scan through the string target. Returns a modified version
of target, where every substring that matches pattern is replaced by the string substitute, with
backslash expansion performed. Equivalent to regexps() with the fg options. If any argument is not
a string, returns ERROR.
Boolean stringList_regexpMember
(String pattern, String list [ , String delimiter ] [ , String options ]) Uses the description of
a regular expression given by string pattern to scan through the list of strings in list. Returns
TRUE when one of the strings in list is a regular expression as described by pattern. The optional
delimiter describes how the list is delimited, and string options modifies how the match is
performed. Returns FALSE if pattern does not match any entries in list. The return value is ERROR,
if any of the arguments are not strings, or if pattern is not a valid regular expression.
String userHome(String userName [ , String default ])
Returns the home directory of the given user as configured on the current system (determined using
the getpwdnam() call). (Returns default if the default argument is passed and the home directory
of the user is not defined.)
List userMap(String mapSetName, String userName)
Map an input string using the given mapping set. Returns a string containing the list of groups to
which the user belongs separated by commas or undefined if the user was not found in the map file.
String userMap(String mapSetName, String userName, String preferredGroup)
Map an input string using the given mapping set. Returns a string, which is the preferred group if
the user is in that group; otherwise it is the first group to which the user belongs, or undefined
if the user belongs to no groups.
String userMap(String mapSetName, String userName, String preferredGroup, String defaultGroup)
Map an input string using the given mapping set. Returns a string, which is the preferred group if
the user is in that group; the first group to which the user belongs, if any; and the default
group if the user belongs to no groups.
The maps for the userMap() function are defined by the following configuration macros:
<SUBSYS>_CLASSAD_USER_MAP_NAMES, CLASSAD_USER_MAPFILE_<name> and CLASSAD_USER_MAPDATA_<name> (see
the admin-manual/configuration-macros:htcondor-wide configuration file entries section).
CLASSAD EVALUATION SEMANTICS
The ClassAd mechanism's primary purpose is for matching entities that supply constraints on candidate
matches. The mechanism is therefore defined to carry out expression evaluations in the context of two
ClassAds that are testing each other for a potential match. For example, the condor_negotiator evaluates
the Requirements expressions of machine and job ClassAds to test if they can be matched. The semantics of
evaluating such constraints is defined below.
Evaluating Literals
Literals are self-evaluating, Thus, integer, string, real, undefined and error values evaluate to
themselves.
Attribute References
Since the expression evaluation is being carried out in the context of two ClassAds, there is a potential
for name space ambiguities. The following rules define the semantics of attribute references made by
ClassAd A that is being evaluated in a context with another ClassAd B:
1. If the reference is prefixed by a scope resolution prefix,
• If the prefix is MY., the attribute is looked up in ClassAd A. If the named attribute does not
exist in A, the value of the reference is UNDEFINED. Otherwise, the value of the reference is the
value of the expression bound to the attribute name.
• Similarly, if the prefix is TARGET., the attribute is looked up in ClassAd B. If the named attribute
does not exist in B, the value of the reference is UNDEFINED. Otherwise, the value of the reference
is the value of the expression bound to the attribute name.
2. If the reference is not prefixed by a scope resolution prefix,
• If the attribute is defined in A, the value of the reference is the value of the expression bound to
the attribute name in A.
• Otherwise, if the attribute is defined in B, the value of the reference is the value of the
expression bound to the attribute name in B.
• Otherwise, if the attribute is defined in the ClassAd environment, the value from the environment is
returned. This is a special environment, to be distinguished from the Unix environment. Currently,
the only attribute of the environment is CurrentTime, which evaluates to the integer value returned
by the system call time(2).
• Otherwise, the value of the reference is UNDEFINED.
3. Finally, if the reference refers to an expression that is itself in the process of being evaluated,
there is a circular dependency in the evaluation. The value of the reference is ERROR.
ClassAd Operators
All operators in the ClassAd language are total, and thus have well defined behavior regardless of the
supplied operands. Furthermore, most operators are strict with respect to ERROR and UNDEFINED, and thus
evaluate to ERROR or UNDEFINED if either of their operands have these exceptional values.
• Arithmetic operators:
1. The operators \*, /, + and - operate arithmetically only on integers and reals.
2. Arithmetic is carried out in the same type as both operands, and type promotions from integers to
reals are performed if one operand is an integer and the other real.
3. The operators are strict with respect to both UNDEFINED and ERROR.
4. If either operand is not a numerical type, the value of the operation is ERROR.
• Comparison operators:
1. The comparison operators ==, !=, <=, <, >= and > operate on integers, reals and strings.
2. String comparisons are case insensitive for most operators. The only exceptions are the operators
=?= and =!=, which do case sensitive comparisons assuming both sides are strings.
3. Comparisons are carried out in the same type as both operands, and type promotions from integers to
reals are performed if one operand is a real, and the other an integer. Strings may not be converted
to any other type, so comparing a string and an integer or a string and a real results in ERROR.
4. The operators ==, !=, <=, <, >=, and > are strict with respect to both UNDEFINED and ERROR.
5. In addition, the operators =?=, is, =!=, and isnt behave similar to == and !=, but are not strict.
Semantically, the =?= and is test if their operands are "identical," i.e., have the same type and
the same value. For example, 10 == UNDEFINED and UNDEFINED == UNDEFINED both evaluate to UNDEFINED,
but 10 =?= UNDEFINED and UNDEFINED is UNDEFINED evaluate to FALSE and TRUE respectively. The =!= and
isnt operators test for the "is not identical to" condition.
=?= and is have the same behavior as each other. And isnt and =!= behave the same as each other. The
ClassAd unparser will always use =?= in preference to is and =!= in preference to isnt when printing
out ClassAds.
• Logical operators:
1. The logical operators && and || operate on integers and reals. The zero value of these types are
considered FALSE and non-zero values TRUE.
2. The operators are not strict, and exploit the "don't care" properties of the operators to squash
UNDEFINED and ERROR values when possible. For example, UNDEFINED && FALSE evaluates to FALSE, but
UNDEFINED || FALSE evaluates to UNDEFINED.
3. Any string operand is equivalent to an ERROR operand for a logical operator. In other words, TRUE &&
"foobar" evaluates to ERROR.
• The Ternary operator:
1. The Ternary operator (expr1 ? expr2 : expr3) operate with expressions. If all three expressions are
given, the operation is strict.
2. However, if the middle expression is missing, eg. expr1 ?: expr3, then, when expr1 is defined, that
defined value is returned. Otherwise, when expr1 evaluated to UNDEFINED, the value of expr3 is
evaluated and returned. This can be a convenient shortcut for writing what would otherwise be a much
longer classad expression.
Expression Examples
The =?= operator is similar to the == operator. It checks if the left hand side operand is identical in
both type and value to the right hand side operand, returning TRUE when they are identical.
CAUTION:
For strings, the comparison is case-insensitive with the == operator and case-sensitive with the =?=
operator. A key point in understanding is that the =?= operator only produces evaluation results of
TRUE and FALSE, where the == operator may produce evaluation results TRUE, FALSE, UNDEFINED, or ERROR.
Table 4.1 presents examples that define the outcome of the == operator. Table 4.2 presents examples that
define the outcome of the =?= operator.
┌──────────────────────────┬──────────────────┐
│ expression │ evaluated result │
├──────────────────────────┼──────────────────┤
│ (10 == 10) │ TRUE │
├──────────────────────────┼──────────────────┤
│ (10 == 5) │ FALSE │
├──────────────────────────┼──────────────────┤
│ (10 == "ABC") │ ERROR │
├──────────────────────────┼──────────────────┤
│ "ABC" == "abc" │ TRUE │
├──────────────────────────┼──────────────────┤
│ (10 == UNDEFINED) │ UNDEFINED │
├──────────────────────────┼──────────────────┤
│ (UNDEFINED == UNDEFINED) │ UNDEFINED │
└──────────────────────────┴──────────────────┘
Table 4.1: Evaluation examples for the == operator
┌───────────────────────────┬──────────────────┐
│ expression │ evaluated result │
├───────────────────────────┼──────────────────┤
│ (10 =?= 10) │ TRUE │
├───────────────────────────┼──────────────────┤
│ (10 =?= 5) │ FALSE │
├───────────────────────────┼──────────────────┤
│ (10 =?= "ABC") │ FALSE │
├───────────────────────────┼──────────────────┤
│ "ABC" =?= "abc" │ FALSE │
├───────────────────────────┼──────────────────┤
│ (10 =?= UNDEFINED) │ FALSE │
├───────────────────────────┼──────────────────┤
│ (UNDEFINED =?= UNDEFINED) │ TRUE │
└───────────────────────────┴──────────────────┘
Table 4.2: Evaluation examples for the =?= operator
The =!= operator is similar to the != operator. It checks if the left hand side operand is not identical
in both type and value to the the right hand side operand, returning FALSE when they are identical.
CAUTION:
For strings, the comparison is case-insensitive with the != operator and case-sensitive with the =!=
operator. A key point in understanding is that the =!= operator only produces evaluation results of
TRUE and FALSE, where the != operator may produce evaluation results TRUE, FALSE, UNDEFINED, or ERROR.
Table 4.3 presents examples that define the outcome of the != operator. Table 4.4 presents examples that
define the outcome of the =!= operator.
┌──────────────────────────┬──────────────────┐
│ expression │ evaluated result │
├──────────────────────────┼──────────────────┤
│ (10 != 10) │ FALSE │
├──────────────────────────┼──────────────────┤
│ (10 != 5) │ TRUE │
├──────────────────────────┼──────────────────┤
│ (10 != "ABC") │ ERROR │
├──────────────────────────┼──────────────────┤
│ "ABC" != "abc" │ FALSE │
├──────────────────────────┼──────────────────┤
│ (10 != UNDEFINED) │ UNDEFINED │
├──────────────────────────┼──────────────────┤
│ (UNDEFINED != UNDEFINED) │ UNDEFINED │
└──────────────────────────┴──────────────────┘
Table 4.3: Evaluation examples for the != operator
┌───────────────────────────┬──────────────────┐
│ expression │ evaluated result │
├───────────────────────────┼──────────────────┤
│ (10 =!= 10) │ FALSE │
├───────────────────────────┼──────────────────┤
│ (10 =!= 5) │ TRUE │
├───────────────────────────┼──────────────────┤
│ (10 =!= "ABC") │ TRUE │
├───────────────────────────┼──────────────────┤
│ "ABC" =!= "abc" │ TRUE │
├───────────────────────────┼──────────────────┤
│ (10 =!= UNDEFINED) │ TRUE │
├───────────────────────────┼──────────────────┤
│ (UNDEFINED =!= UNDEFINED) │ FALSE │
└───────────────────────────┴──────────────────┘
Table 4.4: Evaluation examples for the =!= operator
OLD CLASSADS IN THE HTCONDOR SYSTEM
The simplicity and flexibility of ClassAds is heavily exploited in the HTCondor system. ClassAds are not
only used to represent machines and jobs in the HTCondor pool, but also other entities that exist in the
pool such as submitters of jobs and master daemons. Since arbitrary expressions may be supplied and
evaluated over these ClassAds, users have a uniform and powerful mechanism to specify constraints over
these ClassAds. These constraints can take the form of Requirements expressions in resource and job
ClassAds, or queries over other ClassAds.
Constraints and Preferences
The requirements and rank expressions within the submit description file are the mechanism by which users
specify the constraints and preferences of jobs. For machines, the configuration determines both
constraints and preferences of the machines.
For both machine and job, the rank expression specifies the desirability of the match (where higher
numbers mean better matches). For example, a job ClassAd may contain the following expressions:
Requirements = (Arch == "INTEL") && (OpSys == "LINUX")
Rank = TARGET.Memory + TARGET.Mips
In this case, the job requires a 32-bit Intel processor running a Linux operating system. Among all such
computers, the customer prefers those with large physical memories and high MIPS ratings. Since the Rank
is a user-specified metric, any expression may be used to specify the perceived desirability of the
match. The condor_negotiator daemon runs algorithms to deliver the best resource (as defined by the rank
expression), while satisfying other required criteria.
Similarly, the machine may place constraints and preferences on the jobs that it will run by setting the
machine's configuration. For example,
Friend = Owner == "tannenba" || Owner == "wright"
ResearchGroup = Owner == "jbasney" || Owner == "raman"
Trusted = Owner != "rival" && Owner != "riffraff"
START = Trusted && ( ResearchGroup || LoadAvg < 0.3 && KeyboardIdle > 15*60 )
RANK = Friend + ResearchGroup*10
The above policy states that the computer will never run jobs owned by users rival and riffraff, while
the computer will always run a job submitted by members of the research group. Furthermore, jobs
submitted by friends are preferred to other foreign jobs, and jobs submitted by the research group are
preferred to jobs submitted by friends.
Note: Because of the dynamic nature of ClassAd expressions, there is no a priori notion of an
integer-valued expression, a real-valued expression, etc. However, it is intuitive to think of the
Requirements and Rank expressions as integer-valued and real-valued expressions, respectively. If the
actual type of the expression is not of the expected type, the value is assumed to be zero.
Querying with ClassAd Expressions
The flexibility of this system may also be used when querying ClassAds through the condor_status and
condor_q tools which allow users to supply ClassAd constraint expressions from the command line.
Needed syntax is different on Unix and Windows platforms, due to the interpretation of characters in
forming command-line arguments. The expression must be a single command-line argument, and the resulting
examples differ for the platforms. For Unix shells, single quote marks are used to delimit a single
argument. For a Windows command window, double quote marks are used to delimit a single argument. Within
the argument, Unix escapes the double quote mark by prepending a backslash to the double quote mark.
Windows escapes the double quote mark by prepending another double quote mark. There may not be spaces in
between.
Here are several examples. To find all computers which have had their keyboards idle for more than 60
minutes and have more than 4000 MB of memory, the desired ClassAd expression is
KeyboardIdle > 60*60 && Memory > 4000
On a Unix platform, the command appears as
$ condor_status -const 'KeyboardIdle > 60*60 && Memory > 4000'
Name OpSys Arch State Activity LoadAv Mem ActvtyTime
100
slot1@altair.cs.wi LINUX X86_64 Owner Idle 0.000 8018 13+00:31:46
slot2@altair.cs.wi LINUX X86_64 Owner Idle 0.000 8018 13+00:31:47
...
...
slot1@athena.stat. LINUX X86_64 Unclaimed Idle 0.000 7946 0+00:25:04
slot2@athena.stat. LINUX X86_64 Unclaimed Idle 0.000 7946 0+00:25:05
...
...
The Windows equivalent command is
> condor_status -const "KeyboardIdle > 60*60 && Memory > 4000"
Here is an example for a Unix platform that utilizes a regular expression ClassAd function to list
specific information. A file contains ClassAd information. condor_advertise is used to inject this
information, and condor_status constrains the search with an expression that contains a ClassAd function.
$ cat ad
MyType = "Generic"
FauxType = "DBMS"
Name = "random-test"
Machine = "f05.cs.wisc.edu"
MyAddress = "<128.105.149.105:34000>"
DaemonStartTime = 1153192799
UpdateSequenceNumber = 1
$ condor_advertise UPDATE_AD_GENERIC ad
$ condor_status -any -constraint 'FauxType=="DBMS" && regexp("random.*", Name, "i")'
MyType TargetType Name
Generic None random-test
The ClassAd expression describing a machine that advertises a Windows operating system:
OpSys == "WINDOWS"
Here are three equivalent ways on a Unix platform to list all machines advertising a Windows operating
system. Spaces appear in these examples to show where they are permitted.
$ condor_status -constraint ' OpSys == "WINDOWS" '
$ condor_status -constraint OpSys==\"WINDOWS\"
$ condor_status -constraint "OpSys==\"WINDOWS\""
The equivalent command on a Windows platform to list all machines advertising a Windows operating system
must delimit the single argument with double quote marks, and then escape the needed double quote marks
that identify the string within the expression. Spaces appear in this example where they are permitted.
> condor_status -constraint " OpSys == ""WINDOWS"" "
EXTENDING CLASSADS WITH USER-WRITTEN FUNCTIONS
The ClassAd language provides a rich set of functions. It is possible to add new functions to the ClassAd
language without recompiling the HTCondor system or the ClassAd library. This requires implementing the
new function in the C++ programming language, compiling the code into a shared library, and telling
HTCondor where in the file system the shared library lives.
While the details of the ClassAd implementation are beyond the scope of this document, the ClassAd source
distribution ships with an example source file that extends ClassAds by adding two new functions, named
todays_date() and double(). This can be used as a model for users to implement their own functions. To
deploy this example extension, follow the following steps on Linux:
• Download the ClassAd source distribution from http://www.cs.wisc.edu/condor/classad.
• Unpack the tarball.
• Inspect the source file shared.cpp. This one file contains the whole extension.
• Build shared.cpp into a shared library. On Linux, the command line to do so is
$ g++ -DWANT_CLASSAD_NAMESPACE -I. -shared -o shared.so \
-Wl,-soname,shared.so -o shared.so -fPIC shared.cpp
• Copy the file shared.so to a location that all of the HTCondor tools and daemons can read.
$ cp shared.so `condor_config_val LIBEXEC`
• Tell HTCondor to load the shared library into all tools and daemons, by setting the CLASSAD_USER_LIBS
configuration variable to the full name of the shared library. In this case,
CLASSAD_USER_LIBS = $(LIBEXEC)/shared.so
• Restart HTCondor.
• Test the new functions by running
$ condor_status -format "%s\n" todays_date()
AUTHOR
HTCondor Team
COPYRIGHT
1990-2024, Center for High Throughput Computing, Computer Sciences Department, University of Wisconsin-
Madison, Madison, WI, US. Licensed under the Apache License, Version 2.0.
Jan 04, 2025 CLASSADS(1)