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Chapter 1. Decision model and notation

Decision Model and Notation (DMN) is a standard established by the Object Management Group (OMG) for describing and modeling operational decisions. DMN decision models can be shared between platforms and across organizations so that business analysts and business rules developers are unified in designing and implementing DMN decision services. The DMN standard is similar to and can be used together with the Business Process Model and Notation (BPMN) standard for designing and modeling business processes.

For more information about the background and applications of DMN, see the OMG Decision Model and Notation specification.

1.1. DMN conformance levels

The DMN specification defines three incremental levels of conformance in a software implementation. A product that claims compliance at one level must also be compliant with any preceding levels. For example, a conformance level 3 implementation must also include the supported components in conformance levels 1 and 2. For the formal definitions of each conformance level, see the OMG Decision Model and Notation specification.

The following are summaries of the three DMN conformance levels:

Conformance level 1
A DMN conformance level 1 implementation supports decision requirement diagrams (DRDs), decision logic, and decision tables, but decision models are not executable. Any language can be used to define the expressions, including natural, unstructured languages.
Conformance level 2
A DMN conformance level 2 implementation includes the requirements in conformance level 1, and supports Simplified Friendly Enough Expression Language (S-FEEL) expressions and fully executable decision models.
Conformance level 3

A DMN conformance level 3 implementation includes the requirements in conformance levels 1 and 2, and supports Friendly Enough Expression Language (FEEL) expressions, the full set of boxed expressions, and fully executable decision models.

Note

Red Hat Process Automation Manager includes full runtime support for DMN 1.1 models at conformance level 3, but currently does not include a built-in DMN model editor. Editors for DMN models will be added to the platform in the near future, but meanwhile you can use third-party DMN authoring platforms and implement DMN models in your decision services in Red Hat Process Automation Manager.

1.2. DMN elements

DMN models consist of the following five elements:

  • Decisions: Nodes in the model where one or several inputs determine an output based on decision logic.
  • Input data: Information necessary to determine a decision. This information usually includes business-level concepts or objects relevant to the business, such as a restaurant’s peak business hours and staff availability.
  • Business knowledge models: Reusable pieces of decision logic. Decisions that have the same logic but depend on different sub-inputs or sub-decisions use business knowledge models to determine which procedure to follow.
  • Knowledge sources: External regulations, documents, committees, policies, and so on that shape decision logic. Knowledge sources are references to real-world factors rather than executable business rules.
  • Decision service: A decision service is a top-level decision, with well-defined inputs, that is published as a service for invocation. In the diagram it is represented by an overlay rectangle with round corners. The decision service can be invoked from an external application or business process (BPMN). For more information, see page 36 of the DMN specification document.

Figure 1.1. Basic decision requirements diagram

dmn drg

1.3. Rule expressions in FEEL

Friendly Enough Expression Language (FEEL) is an expression language defined by the OMG DMN specification. FEEL expressions define the logic of a decision in a DMN model. FEEL is designed to facilitate both decision modeling and execution by assigning semantics to the decision model constructs. FEEL expressions in decision requirements diagrams (DRDs) occupy either table cells in decision tables or decision nodes.

For more information about FEEL in DMN, see the OMG Decision Model and Notation specification.

1.3.1. Variable and function names in FEEL

Unlike many traditional expression languages, Friendly Enough Expression Language (FEEL) supports spaces and a few special characters as part of variable and function names. A FEEL name must start with a letter, ?, or _ element. The unicode letter characters are also allowed. Variable names cannot start with a language keyword, such as and, true, or every. The remaining characters in a variable name can be any of the starting characters, as well as digits, white spaces, and special characters such as +, -, /, *, ', and ..

For example, the following names are all valid FEEL names:

  • Age
  • Birth Date
  • Flight 234 pre-check procedure

Several limitations apply to variable and function names in FEEL:

Ambiguity
The use of spaces, keywords, and other special characters as part of names can make FEEL ambiguous. The ambiguities are resolved in the context of the expression, matching names from left to right. The parser resolves the variable name as the longest name matched in scope. You can use ( ) to disambiguate names if necessary.
Spaces in names

The DMN specification limits the use of spaces in FEEL names. According to the DMN specification, names can contain multiple spaces but not two consecutive spaces.

In order to make the language easier to use and avoid common errors due to spaces, Red Hat Process Automation Manager removes the limitation on the use of consecutive spaces. Red Hat Process Automation Manager supports variable names with any number of consecutive spaces, but normalizes them into a single space. For example, the two variable references First Name and First Name are both acceptable in Red Hat Process Automation Manager.

Red Hat Process Automation Manager also normalizes the use of other white spaces, like the non-breakable white space that is common in web pages, tabs, and line breaks. From a Red Hat Process Automation Manager FEEL engine perspective, all of these characters are normalized into a single white space before processing.

The keyword in
The keyword in is the only keyword in the language that cannot be used as part of a variable name. Although the specifications allow the use of keywords in the middle of variable names, the use of in in variable names conflicts with the grammar definition of for, every and some expression constructs.

1.3.2. Data types in FEEL

Friendly Enough Expression Language (FEEL) supports the following data types:

  • Numbers
  • Strings
  • Boolean values
  • Dates
  • Time
  • Date and time
  • Days and time duration
  • Years and months duration
  • Functions
  • Contexts
  • Ranges (or intervals)
  • Lists
Note

Functions, contexts, ranges, and lists are not explicitly supported in the DMN specification as data types, but they are supported by extension in Red Hat Process Automation Manager.

The following are descriptions of each data type:

Numbers

Numbers in FEEL are based on the IEEE 754-2008 Decimal 128 format, with 34 digits of precision. Internally, numbers are represented in Java as BigDecimals with MathContext DECIMAL128. FEEL supports only one number data type, so the same type is used to represent both integers and floating point numbers.

FEEL numbers use a dot (.) as a decimal separator. FEEL does not support -INF, +INF, or NaN. FEEL uses null to represent invalid numbers.

Red Hat Process Automation Manager extends the DMN specification and supports additional number notations:

  • Scientific: You can use scientific notation with the suffix e<exp> or E<exp>. For example, 1.2e3 is the same as writing the expression 1.2*10**3, but is a literal instead of an expression.
  • Hexadecimal: You can use hexadecimal numbers with the prefix 0x. For example, 0xff is the same as the decimal number 255. Both uppercase and lowercase letters are supported. For example, 0XFF is the same as 0xff.
  • Type suffixes: You can use the type suffixes f, F, d, D, l, and L. These suffixes are ignored.
Strings

Strings in FEEL are any sequence of characters delimited by double quotation marks.

Example: 

"John Doe"
Boolean values
FEEL uses three-valued boolean logic, so a boolean logic expression may have values true, false, or null.
Dates

FEEL does not have date literals, but you can use the built-in date() function to construct date values. Date strings in FEEL follow the format defined in the XML Schema Part 2: Datatypes document. The format is "YYYY-MM-DD" where YYYY is the year with four digits, MM is the number of the month with two digits, and DD is the number of the day.

Example: 

date( "2017-06-23" )

Date objects have time equal to "00:00:00", which is midnight. The dates are considered to be local, without a timezone.

Time

FEEL does not have time literals, but you can use the built-in time() function to construct time values. Time strings in FEEL follow the format defined in the XML Schema Part 2: Datatypes document. The format is "hh:mm:ss[.uuu][(+-)hh:mm]" where hh is the hour of the day (from 00 to 23), mm is the minutes in the hour, and ss is the number of seconds in the minute. Optionally, the string may define the number of milliseconds (uuu) within the second and contain a positive (+) or negative (-) offset from UTC time to define its timezone. Instead of using an offset, you can use the letter z to represent the UTC time, which is the same as an offset of -00:00. If no offset is defined, the time is considered to be local.

Examples: 

time( "04:25:12" )
time( "14:10:00+02:00" )
time( "22:35:40.345-05:00" )
time( "15:00:30z" )

Time values that define an offset or a timezone cannot be compared to local times that do not define an offset or a timezone.

Date and time

FEEL does not have date and time literals, but you can use the built-in date and time() function to construct date and time values. Date and time strings in FEEL follow the format defined in the XML Schema Part 2: Datatypes document. The format is "<date>T<time>", where <date> and <time> follow the prescribed XML schema formatting, conjoined by T.

Examples: 

date and time( "2017-10-22T23:59:00" )
date and time( "2017-06-13T14:10:00+02:00" )
date and time( "2017-02-05T22:35:40.345-05:00" )
date and time( "2017-06-13T15:00:30z" )

Date and time values that define an offset or a timezone cannot be compared to local date and time values that do not define an offset or a timezone.

Important

If your implementation of the DMN specification does not support spaces in the XML schema, use the keyword dateTime as a synonym of date and time.

Days and time duration

FEEL does not have days and time duration literals, but you can use the built-in duration() function to construct days and time duration values. Days and time duration strings in FEEL follow the format defined in the XML Schema Part 2: Datatypes document, but are restricted to only days, hours, minutes and seconds. Months and years are not supported.

Examples: 

duration( "P1DT23H12M30S" )
duration( "P23D" )
duration( "PT12H" )
duration( "PT35M" )
Important

If your implementation of the DMN specification does not support spaces in the XML schema, use the keyword dayTimeDuration as a synonym of days and time duration.

Years and months duration

FEEL does not have years and months duration literals, but you can use the built-in duration() function to construct days and time duration values. Years and months duration strings in FEEL follow the format defined in the XML Schema Part 2: Datatypes document, but are restricted to only years and months. Days, hours, minutes, or seconds are not supported.

Examples: 

duration( "P3Y5M" )
duration( "P2Y" )
duration( "P10M" )
duration( "P25M" )
Important

If your implementation of the DMN specification does not support spaces in the XML schema, use the keyword yearMonthDuration as a synonym of years and months duration.

Functions

FEEL supports function literals (or anonymous functions) that you can use to create functions. FEEL does not provide an explicit way of declaring a variable as a function in the DMN specification, but Red Hat Process Automation Manager extends the DMN built-in types to support functions.

Example: 

function(a, b) a + b

In this example, the FEEL expression creates a function that adds the parameters a and b and returns the result.

Important

A function datatype is an extension of the DMN specification and is subject to change if the DMN specification provides a standard way to declare functions in the future.

Contexts

FEEL supports context literals that you can use to create contexts. A context in FEEL is a list of key and value pairs, similar to maps in languages like Java. FEEL does not provide an explicit way of declaring a variable as a context in the DMN specification, but Red Hat Process Automation Manager extends the DMN built-in types to support contexts.

Example: 

{ x : 5, y : 3 }

In this example, the expression creates a context with two entries, x and y, representing a coordinate in a chart.

In DMN 1.1, another way to create contexts is to create an item definition that contains the list of keys as attributes, and then declare the variable as having that item definition type.

The Red Hat Process Automation Manager DMN API supports DMN ItemDefinition structural types in a DMNContext represented in two ways:

  • User-defined Java type: Must be a valid JavaBeans object defining properties and getters for each of the components in the DMN ItemDefinition. If necessary, you can also use the @FEELProperty annotation for those getters representing a component name which would result in an invalid Java identifier.
  • java.util.Map interface: The map needs to define the appropriate entries, with the keys corresponding to the component name in the DMN ItemDefinition.
Important

A context data type is an extension of the DMN specification and is subject to change if the DMN specification provides a standard way to declare contexts in the future.

Ranges (or intervals)

FEEL supports range literals that you can use to create ranges or intervals. A range in FEEL is a value that defines a lower and an upper bound, where either can be open or closed. FEEL does not provide an explicit way of declaring a variable as a range in the DMN specification (unless it is within another expression), but Red Hat Process Automation Manager extends the DMN built-in types to support ranges.

The syntax of a range is defined in the following formats: 

range          := interval_start endpoint '..' endpoint interval_end
interval_start := open_start | closed_start
open_start     := '(' | ']'
closed_start   := '['
interval_end   := open_end | closed_end
open_end       := ')' | '['
closed_end     := ']'
endpoint       := expression

The expression for the endpoint must return a comparable value, and the lower bound endpoint must be lower than the upper bound endpoint.

For example, the following literal expression defines an interval between 1 and 10, including the boundaries (a closed interval on both endpoints): 

[ 1 .. 10 ]

The following literal expression defines an interval between 1 hour and 12 hours, including the lower boundary (a closed interval), but excluding the upper boundary (an open interval): 

[ duration("PT1H") .. duration("PT12H") ]

You can use ranges in decision tables to test for ranges of values, or use ranges in simple literal expressions. For example, the following literal expression returns true if the value of a variable x is between 0 and 100: 

x in [ 1 .. 100 ]
Important

A range data type is an extension of the DMN specification and is subject to change if the DMN specification provides a standard way to declare contexts in the future.

Lists

Lists in FEEL are represented by a comma-separated list of values enclosed in square brackets. FEEL does not provide an explicit way of declaring a variable as a list in the DMN specification, but Red Hat Process Automation Manager extends the DMN built-in types to support contexts.

Example: 

[ 2, 3, 4, 5 ]

All lists in FEEL contain elements of the same type and are immutable. Elements in a list can be accessed by index, where the first element is 1. Negative indexes can access elements starting from the end of the list so that -1 is the last element.

For example, the following expression returns the second element of a list x: 

x[2]

The following expression returns the second-to-last element of a list x: 

x[-2]
Important

A list data type is an extension of the DMN specification and is subject to change if the DMN specification provides a standard way to declare contexts in the future.

1.4. DMN decision tables

A decision table in DMN is a visual representation of one or more rules in a tabular format. Each rule consists of a single row in the table, and includes columns that define the conditions and outcome for that particular row. The definition of each row is precise enough to derive the outcome using the values of the conditions. For readability purposes, there is often a means to hide some of the more technical details when viewing the table.

Figure 1.2. Decision table example

dmn decision table example2

Decision tables are a popular way for modeling rules and decisions, and are used in many methodologies (such as DMN) and implementation frameworks (such as Drools used in Red Hat Process Automation Manager).

Important

Although the concept of decision tables is similar in DMN and Drools, DMN decision tables syntax and layout are defined by the DMN standard while Drools decision tables are defined by the Drools project. Red Hat Process Automation Manager supports both formats of decision tables, but they are not interchangeable. For more information about Drools decision tables, see Designing a decision service using uploaded decision tables.

1.4.1. Hit policies

Hit policies define how to reach an outcome when multiple rules match on a single decision table. Decision modelers select one of the following five policies for reaching an outcome and then specify that policy by placing an indicator in the table’s upper-left corner. In the following list, the indicators are listed after the indicator type, in parentheses ().

  • Unique (U): Permits only one rule to match. Any overlap raises an error.
  • Any (A): Permits multiple rules to match, but they must all have the same output. If multiple matching rules do not have the same output, an error is raised.
  • Priority (P): Permits multiple rules to match, with different outputs. The output that comes first in the output values list is selected.
  • First (F): Uses the first match in rule order.

  • Collect (C+, C>, C<, C#): Aggregates output from multiple rules based on an aggregation function.

    • Collect ( C ): Aggregates values in an arbitrary list.
    • Collect Sum (C+): Outputs the sum of all collected values. Values must be numeric.
    • Collect Min (C<): Outputs the minimum value among the matches. The resulting values must be comparable, such as numbers, dates, or text (lexicographic order).
    • Collect Max (C>): Outputs the maximum value among the matches. The resulting values must be comparable, such as numbers, dates or text (lexicographic order).
    • Collect Count (C#): Outputs the number of matching rules.

1.5. Boxed expressions

Boxed expressions are tabular representations of contexts, function definitions, function invocations, and other expressions in a DMN model. For example, the following boxed expression defines the function Installment calculation that uses four parameters (Product, Rate, Term, and Amount) and calculates the monthly installment amount.

Figure 1.3. Boxed expression example

dmn boxed expression example