Vienna Development Method
The Vienna Development Method is one of the longest-established formal methods for the development of computer-based systems. Originating in work done at the IBM Laboratory Vienna in the 1970s, it has grown to include a group of techniques and tools based on a formal specification language—the VDM Specification Language. It has an extended form, VDM++, which supports the modeling of object-oriented and concurrent systems. Support for VDM includes commercial and academic tools for analyzing models, including support for testing and proving properties of models and generating program code from validated VDM models. There is a history of industrial usage of VDM and its tools and a growing body of research in the formalism has led to notable contributions to the engineering of critical systems, compilers, concurrent systems and in logic for computer science.
Philosophy
Computing systems may be modeled in VDM-SL at a higher level of abstraction than is achievable using programming languages, allowing the analysis of designs and identification of key features, including defects, at an early stage of system development. Models that have been validated can be transformed into detailed system designs through a refinement process. The language has a formal semantics, enabling proof of the properties of models to a high level of assurance. It also has an executable subset, so that models may be analyzed by testing and can be executed through graphical user interfaces, so that models can be evaluated by experts who are not necessarily familiar with the modeling language itself.History
The origins of VDM-SL lie in the IBM Laboratory in Vienna where the first version of the language was called the Vienna Definition Language. The VDL was essentially used for giving operational semantics descriptions in contrast to the VDM – Meta-IV which provided denotational semantics
«Towards the end of 1972 the Vienna group again turned their attention to the problem of systematically developing a compiler from a language definition. The overall approach adopted has been termed the "Vienna Development Method"... The meta-language actually adopted is used to define major portions of PL/1 in BEKIČ 74.»
There is no connection between Meta-IV, and Schorre's Meta-II language, or its successor Tree Meta; these were compiler-compiler systems rather than being suitable for formal problem descriptions.
So Meta-IV was "used to define major portions of" the PL/I programming language. Other programming languages retrospectively described, or partially described, using Meta-IV and VDM-SL include the BASIC programming language, FORTRAN, the APL programming language, ALGOL 60, the Ada programming language and the Pascal programming language. Meta-IV evolved into several variants, generally described as the Danish, English and Irish Schools.
The "English School" derived from work by Cliff Jones on the aspects of VDM not specifically related to language definition and compiler design. It stresses modelling persistent state through the use of data types constructed from a rich collection of base types. Functionality is typically described through operations which may have side-effects on the state and which are mostly specified implicitly using a precondition and postcondition. The "Danish School" has tended to stress a constructive approach with explicit operational specification used to a greater extent. Work in the Danish school led to the first European validated Ada compiler.
An ISO Standard for the language was released in 1996.
VDM features
The VDM-SL and VDM++ syntax and semantics are described at length in the VDMTools language manuals and in the available texts. The ISO Standard contains a formal definition of the language's semantics. In the remainder of this article, the ISO-defined interchange syntax is used. Some texts prefer a more concise mathematical syntax.A VDM-SL model is a system description given in terms of the functionality performed on data. It consists of a series of definitions of data types and functions or operations performed upon them.
Basic types: numeric, character, token and quote types
VDM-SL includes basic types modelling numbers and characters as follows:bool | Boolean datatype | false, true |
nat | natural numbers | 0, 1, 2, 3, 4, 5... |
nat1 | natural numbers | 1, 2, 3, 4, 5,... |
int | integers | ..., −3, −2, −1, 0, 1, 2, 3,... |
rat | rational numbers | a/b, where a and b are integers, b is not 0 |
real | real numbers | ... |
char | characters | A, B, C,... |
token | structureless tokens | ... |
| the quote type containing the value
| ... |
Data types are defined to represent the main data of the modelled system. Each type definition introduces a new type name and gives a representation in terms of the basic types or in terms of types already introduced. For example, a type modelling user identifiers for a log-in management system might be defined as follows:
types
UserId = nat
For manipulating values belonging to data types, operators are defined on the values. Thus, natural number addition, subtraction etc. are provided, as are Boolean operators such as equality and inequality. The language does not fix a maximum or minimum representable number or a precision for real numbers. Such constraints are defined where they are required in each model by means of data type invariants—Boolean expressions denoting conditions that must be respected by all elements of the defined type. For example, a requirement that user identifiers must be no greater than 9999 would be expressed as follows :
UserId = nat
inv uid uid <= 9999
Since invariants can be arbitrarily complex logical expressions, and membership of a defined type is limited to only those values satisfying the invariant, type correctness in VDM-SL is not automatically decidable in all situations.
The other basic types include char for characters. In some cases, the representation of a type is not relevant to the model's purpose and would only add complexity. In such cases, the members of the type may be represented as structureless tokens. Values of token types can only be compared for equality – no other operators are defined on them. Where specific named values are required, these are introduced as quote types. Each quote type consists of one named value of the same name as the type itself. Values of quote types may only be compared for equality.
For example, in modelling a traffic signal controller, it may be convenient to define values to represent the colours of the traffic signal as quote types:
Type constructors: union, product and composite types
The basic types alone are of limited value. New, more structured data types are built using type constructors.
| Union of types T1,...,Tn |
T1*T2*...*Tn | Cartesian product of types T1,...,Tn |
T :: f1:T1... fn:Tn | Composite type |
The most basic type constructor forms the union of two predefined types. The type
contains all elements of the type A and all of the type B
. In the traffic signal controller example, the type modelling the colour of a traffic signal could be defined as follows:SignalColour =
Enumerated types in VDM-SL are defined as shown above as unions on quote types.
Cartesian product types may also be defined in VDM-SL. The type
is the type composed of all tuples of values, the first element of which is from the type A1
and the second from the type A2
and so on. The composite or record type is a Cartesian product with labels for the fields. The typeT :: f1:A1
f2:A2
...
fn:An
is the Cartesian product with fields labelled
f1,…,fn
. An element of type T
can be composed from its constituent parts by a constructor, written mk_T
. Conversely, given an element of type T
, the field names can be used to select the named component. For example, the typeDate :: day:nat1
month:nat1
year:nat
inv mk_Date d <=31 and m<=12
models a simple date type. The value
mk_Date
corresponds to 1 April 2001. Given a date d
, the expression d.month
is a natural number representing the month. Restrictions on days per month and leap years could be incorporated into the invariant if desired. Combining these:mk_Date.month = 4
Collections
Collection types model groups of values. Sets are finite unordered collections in which duplication between values is suppressed. Sequences are finite ordered collections in which duplication may occur and mappings represent finite correspondences between two sets of values.Sets
The set type constructor constructs the type composed of all finite sets of values drawn from the typeT
. For example, the type definitionUGroup = set of UserId
defines a type
UGroup
composed of all finite sets of UserId
values. Various operators are defined on sets for constructing their union, intersections, determining proper and non-strict subset relationships etc.
| Set enumeration: the set of elements a , b and c |
| Set comprehension: the set of x from type T such that P |
| The set of integers in the range i to j |
e in set s | e is an element of set s |
e not in set s | e is not an element of set s |
s1 union s2 | Union of sets s1 and s2 |
s1 inter s2 | Intersection of sets s1 and s2 |
s1 \ s2 | Set difference of sets s1 and s2 |
dunion s | Distributed union of set of sets s |
s1 psubset s2 | s1 is a subset of s2 |
s1 subset s2 | s1 is a subset of s2 |
card s | The cardinality of set s |
Sequences
The finite sequence type constructor constructs the type composed of all finite lists of values drawn from the typeT
. For example, the type definitionString = seq of char
Defines a type
String
composed of all finite strings of characters. Various operators are defined on sequences for constructing concatenation, selection of elements and subsequences etc. Many of these operators are partial in the sense that they are not defined for certain applications. For example, selecting the 5th element of a sequence that contains only three elements is undefined.The order and repetition of items in a sequence is significant, so
is not equal to
, and
is not equal to
.
| Sequence enumeration: the sequence of elements a , b and c |
| Sequence comprehension: sequence of expressions f for each x of type T such that P holds |
hd s | The head of s |
tl s | The tail of s |
len s | The length of s |
elems s | The set of elements of s |
s | The i th element of s |
inds s | the set of indices for the sequence s |
s1^s2 | the sequence formed by concatenating sequences s1 and s2 |
Maps
A finite mapping is a correspondence between two sets, the domain and range, with the domain indexing elements of the range. It is therefore similar to a finite function. The mapping type constructor in VDM-SL constructs the type composed of all finite mappings from sets ofT1
values to sets of T2
values. For example, the type definitionBirthdays = map String to Date
Defines a type
Birthdays
which maps character strings to Date
. Again, operators are defined on mappings for indexing into the mapping, merging mappings, overwriting extracting sub-mappings.Structuring
The main difference between the VDM-SL and VDM++ notations are the way in which structuring is dealt with. In VDM-SL there is a conventional modular extension whereas VDM++ has a traditional object-oriented structuring mechanism with classes and inheritance.Structuring in VDM-SL
In the ISO standard for VDM-SL there is an informative annex that contains different structuring principles. These all follow traditional information hiding principles with modules and they can be explained as:- Module naming: Each module is syntactically started with the keyword
module
followed by the name of the module. At the end of a module the keywordend
is written followed again by the name of the module. - Importing: It is possible to import definitions that has been exported from other modules. This is done in an imports section that is started off with the keyword
imports
and followed by a sequence of imports from different modules. Each of these module imports are started with the keywordfrom
followed by the name of the module and a module signature. The module signature can either simply be the keywordall
indicating the import of all definitions exported from that module, or it can be a sequence of import signatures. The import signatures are specific for types, values, functions and operations and each of these are started with the corresponding keyword. In addition these import signatures name the constructs that there is a desire to get access to. In addition optional type information can be present and finally it is possible to rename each of the constructs upon import. For types one needs also to use the keywordstruct
if one wish to get access to the internal structure of a particular type. - Exporting: The definitions from a module that one wish other modules to have access to are exported using the keyword
exports
followed by an exports module signature. The exports module signature can either simply consist of the keywordall
or as a sequence of export signatures. Such export signatures are specific for types, values, functions and operations and each of these are started with the corresponding keyword. In case one wish to export the internal structure of a type the keywordstruct
must be used. - More exotic features: In earlier versions of the VDM-SL tools there was also support for parameterized modules and instantiations of such modules. However, these features was taken out of VDMTools around 2000 because they was hardly ever used in industrial applications and there was a substantial number of tool challenges with these features.
Structuring in VDM++
- Class: Each class is syntactically started with the keyword
class
followed by the name of the class. At the end of a class the keywordend
is written followed again by the name of the class. - Inheritance: In case a class inherits constructs from other classes the class name in the class heading can be followed by the keywords
is subclass of
followed by a comma-separated list of names of superclasses. - Access modifiers: Information hiding in VDM++ is done in the same way as in most object oriented languages using access modifiers. In VDM++ definitions are per default private but in front of all definitions it is possible to use one of the access modifier keywords:
private
,public
andprotected
.Modelling functionality
Functional modelling
In VDM-SL, functions are defined over the data types defined in a model. Support for abstraction requires that it should be possible to characterize the result that a function should compute without having to say how it should be computed. The main mechanism for doing this is the implicit function definition in which, instead of a formula computing a result, a logical predicate over the input and result variables, termed a postcondition, gives the result's properties. For example, a functionSQRT
for calculating a square root of a natural number might be defined as follows:SQRTr:real
post r*r = x
Here the postcondition does not define a method for calculating the result
r
but states what properties can be assumed to hold of it. Note that this defines a function that returns a valid square root; there is no requirement that it should be the positive or negative root. The specification above would be satisfied, for example, by a function that returned the negative root of 4 but the positive root of all other valid inputs. Note that functions in VDM-SL are required to be deterministic so that a function satisfying the example specification above must always return the same result for the same input.A more constrained function specification is arrived at by strengthening the postcondition. For example, the following definition constrains the function to return the positive root.
SQRTr:real
post r*r = x and r>=0
All function specifications may be restricted by preconditions which are logical predicates over the input variables only and which describe constraints that are assumed to be satisfied when the function is executed. For example, a square root calculating function that works only on positive real numbers might be specified as follows:
SQRTPr:real
pre x >=0
post r*r = x and r>=0
The precondition and postcondition together form a contract that to be satisfied by any program claiming to implement the function. The precondition records the assumptions under which the function guarantees to return a result satisfying the postcondition. If a function is called on inputs that do not satisfy its precondition, the outcome is undefined.
VDM-SL also supports the definition of executable functions in the manner of a functional programming language. In an explicit function definition, the result is defined by means of an expression over the inputs. For example, a function that produces a list of the squares of a list of numbers might be defined as follows:
SqList: seq of nat -> seq of nat
SqList if s = then else ^ SqList
This recursive definition consists of a function signature giving the types of the input and result and a function body. An implicit definition of the same function might take the following form:
SqListImpr:seq of nat
post len r = len s and
forall i in set inds s & r = s**2
The explicit definition is in a simple sense an implementation of the implicitly specified function. The correctness of an explicit function definition with respect to an implicit specification may be defined as follows.
Given an implicit specification:
fr:T_r
pre pre-f
post post-f
and an explicit function:
f:T_p -> T_r
we say it satisfies the specification iff:
forall p in set T_p & pre-f => f:T_r and post-f
So, "
f
is a correct implementation" should be interpreted as "f
satisfies the specification".State-based modelling
In VDM-SL, functions do not have side-effects such as changing the state of a persistent global variable. This is a useful ability in many programming languages, so a similar concept exists; instead of functions, operations are used to change state variables.For example, if we have a state consisting of a single variable
someStateRegister : nat
, we could define this in VDM-SL as:state Register of
someStateRegister : nat
end
In VDM++ this would instead be defined as:
instance variables
someStateRegister : nat
An operation to load a value into this variable might be specified as:
LOAD
ext wr someStateRegister:nat
post someStateRegister = i
The externals clause specifies which parts of the state can be accessed by the operation;
rd
indicating read-only access and wr
being read/write access.Sometimes it is important to refer to the value of a state before it was modified; for example, an operation to add a value to the variable may be specified as:
ADD
ext wr someStateRegister : nat
post someStateRegister = someStateRegister~ + i
Where the
~
symbol on the state variable in the postcondition indicates the value of the state variable before execution of the operation.Examples
The ''max'' function
This is an example of an implicit function definition. The function returns the largest element from a set of positive integers:maxr:nat
pre card s > 0
post r in set s and
forall r' in set s & r' <= r
The postcondition characterizes the result rather than defining an algorithm for obtaining it. The precondition is needed because no function could return an r in set s when the set is empty.
Natural number multiplication
multpr:natpre true
post r = i*j
Applying the proof obligation
forall p:T_p & pre-f => f:T_r and post-f
to an explicit definition of multp
:multp
if i=0
then 0
else if is-even
then 2*multp
else j+multp
Then the proof obligation becomes:
forall i, j : nat & multp:nat and multp = i*j
This can be shown correct by:
- Proving that the recursion ends
- Mathematical induction
Queue abstract data type
Qelt
. The representation is Qelt
is immaterial and so is defined as a token type.types
Qelt = token;
Queue = seq of Qelt;
state TheQueue of
q : Queue
end
operations
ENQUEUE
ext wr q:Queue
post q = q~ ^ ;
DEQUEUEe:Qelt
ext wr q:Queue
pre q <>
post q~ = ^q;
IS-EMPTYr:bool
ext rd q:Queue
post r <=>
Bank system example
As a very simple example of a VDM-SL model, consider a system for maintaining details of customer bank account. Customers are modelled by customer numbers, accounts are modelled by account numbers. The representations of customer numbers are held to be immaterial and so are modelled by a token type. Balances and overdrafts are modelled by numeric types.AccNum = token;
CustNum = token;
Balance = int;
Overdraft = nat;
AccData :: owner : CustNum
balance : Balance
state Bank of
accountMap : map AccNum to AccData
overdraftMap : map CustNum to Overdraft
inv mk_Bank for all a in set rng accountMap & a.owner in set dom overdraftMap and
a.balance >= -overdraftMap
With operations:
NEWC allocates a new customer number:
operations
NEWCr : CustNum
ext wr overdraftMap : map CustNum to Overdraft
post r not in set dom ~overdraftMap and overdraftMap = ~overdraftMap ++ ;
NEWAC allocates a new account number and sets the balance to zero:
NEWACr : AccNum
ext wr accountMap : map AccNum to AccData
rd overdraftMap map CustNum to Overdraft
pre cu in set dom overdraftMap
post r not in set dom accountMap~ and accountMap = accountMap~ ++
ACINF returns all the balances of all the accounts of a customer, as a map of account number to balance:
ACINFr : map AccNum to Balance
ext rd accountMap : map AccNum to AccData
post r =
Tool support
A number of different tools support VDM:- are the leading commercial tools for VDM and VDM++, owned, marketed, maintained and developed by , building on earlier versions developed by the Danish Company IFAD. The and a practical are available. All licenses are available, free of charge, for the full version of the tool. The full version includes automatic code generation for Java and C++, dynamic link library and CORBA support.
- is a community-based open source initiative aimed at providing freely available tool support for VDM++ on top of the Eclipse platform. Its aim is to develop a framework for interoperable tools that will be useful for industrial application, research and education.
- is a collection of Emacs packages for writing VDM specifications using VDM-SL, VDM++ and VDM-RT. It supports syntax highlighting and editing, on-the-fly syntax checking, template completion and interpreter support.
- : from Adelard provides syntax checking, some simple semantic checking, and generation of a LaTeX file enabling specifications to be printed in mathematical notation. This tool is freely available but it is not being further maintained.
- LaTeX and LaTeX2e macros are available to support the presentation of VDM models in the ISO Standard Language's mathematical syntax. They have been developed and are maintained by the National Physical Laboratory in the UK. and the are available online.
Industrial experience
- Ada and CHILL compilers: The first European validated Ada compiler was developed by Dansk Datamatik Center using VDM. Likewise the semantics of CHILL and Modula-2 were described in their standards using VDM.
- ConForm: An experiment at British Aerospace comparing the conventional development of a trusted gateway with a development using VDM.
- Dust-Expert: A project carried out by Adelard in the UK for a safety related application determining that the safety is appropriate in the layout of industrial plants.
- The development of VDMTools: Most components of the VDMTools tool suite are themselves developed using VDM. This development has been made at in Denmark and CSK in Japan.
- TradeOne: Certain key components of the TradeOne back-office system developed by CSK systems for the Japanese stock exchange were developed using VDM. Comparative measurements exist for developer productivity and defect density of the VDM-developed components versus the conventionally developed code.
- FeliCa Networks have reported the development of an operating system for an integrated circuit for cellular telephone applications.
Refinement
Data reification develops the abstract data types into more concrete data structures, while operation decomposition develops the implicit specifications of operations and functions into algorithms that can be directly implemented in a computer language of choice.
Data reification
Data reification involves finding a more concrete representation of the abstract data types used in a specification. There may be several steps before an implementation is reached. Each reification step for an abstract data representationABS_REP
involves proposing a new representation NEW_REP
. In order to show that the new representation is accurate, a retrieve function is defined that relates NEW_REP
to ABS_REP
, i.e. retr : NEW_REP -> ABS_REP
. The correctness of a data reification depends on proving adequacy, i.e.forall a:ABS_REP & exists r:NEW_REP & a = retr
Since the data representation has changed, it is necessary to update the operations and functions so that they operate on
NEW_REP
. The new operations and functions should be shown to preserve any data type invariants on the new representation. In order to prove that the new operations and functions model those found in the original specification, it is necessary to discharge two proof obligations:- Domain rule:
- Modelling rule:
Example data reification
In a business security system, workers are given ID cards; these are fed into card readers on entry to and exit from the factory.Operations required:
-
INIT
initialises the system, assumes that the factory is empty -
ENTER
-
EXIT
records that a worker is exiting the factory -
IS-PRESENT r : bool
checks to see if a specified worker is in the factory or not
types
Person = token;
Workers = set of Person;
state AWCCS of
pres: Workers
end
operations
INIT
ext wr pres: Workers
post pres = ;
ENTER
ext wr pres : Workers
pre p not in set pres
post pres = pres~ union ;
EXIT
ext wr pres : Workers
pre p in set pres
post pres = pres~\;
IS-PRESENT r : bool
ext rd pres : Workers
post r <=> p in set pres~
As most programming languages have a concept comparable to a set, the first step from the specification is to represent the data in terms of a sequence. These sequences must not allow repetition, as we do not want the same worker to appear twice, so we must add an invariant to the new data type. In this case, ordering is not important, so
is the same as
.The Vienna Development Method is valuable for model-based systems. It is not appropriate if the system is time-based. For such cases, the calculus of communicating systems is more useful.