
A very brief introduction to programming in SPAD
 SPAD is an ordinary programming language, just like C, Java, and Python.
 The name SPAD comes from ScratchPad, which was the original name of the sytem FriCAS developed from.
 SPAD programs are ordinary text files that will be compiled to machine code by the
SPAD compiler that comes with FriCAS.
 SPAD is a statically typed language with type levels.
 Elements: These are the basic data objects.
Examples are:
42 , 3.14159265 , "abc" , [3,5,11] .
They are what one usually considers as values in other programming languages.
 Domains: These are the types of elements.
For example,
Integer is a type for 42 , 3.14 is of type Float ,
"abc" is of type String , [1,2,4,8] is of type List(Integer) . Domains are comparable to classes in object oriented programming languages.
 Categories: These are the types of domains.
For example,
Integer is of type IntegerNumberSystem , String is of type StringCategory ,
List(Integer) is of type ListAggregate(Integer) . Categories are somewhat comparable to interfaces in Java, but are much more powerful.
 The highest type level is the constant keyword
Category .
In other words, categories like IntegerNumberSystem , StringCategory , ListAggregate(Integer) are of
type Category .
 SPAD programs are usually definitions of categories and domains whose functionality will
later be used in an interactive session or by other definitions.
 While categories define the exports of domains, i.e. which functions are provided,
domains themselves implement the corresponding functions.
 Domains form a type hierarchy where only inheritance from one other domain is allowed.
 Categories form a type hierarchy with a multiple inheritance mechanism.
 Categories and domains are often called constructors and (as shown above) can be parametrized.
 SPAD has only very few builtin constructors. Most of the constructors are defined in a library.
Builtin are
Record , Tuple , Join , Mapping (abbreviated via > ).
Library defined are Integer , List , String , Symbol , Monoid , Field , etc.
A running example
Let us start with a little program.
We do not to rely on any previously defined library, but we prefix every constructor with My
in order to avoid name conflicts with existing names.
Our goal is to provide a domain MyFun that is parametrized by a domain S and represents functions
from S into itself. We would like to be able to turn any function of type S > S
into an element of the MyFun(S) domain. Furthermore, we want to turn this domain into a
monoid MyMonoid .
First we define the category MyMonoid .
spad )abbrev category MYMON MyMonoid
MyMonoid: Category == with
1: %
_*: (%, %) > %
spad Compiling FriCAS source code from file
/var/lib/zope2.10/instance/axiomwiki/var/LatexWiki/390450859593423367425px001.spad
using old system compiler.
MYMON abbreviates category MyMonoid

initializing NRLIB MYMON for MyMonoid
compiling into NRLIB MYMON
;;; *** MyMonoid REDEFINED
Time: 0.01 SEC.
finalizing NRLIB MYMON
Processing MyMonoid for Browser database:
>>MyMonoid(constructor): Not documented!!!!
>>MyMonoid(((One) (%) constant)): Not documented!!!!
>>MyMonoid((* (% % %))): Not documented!!!!
>>MyMonoid(): Missing Description
; compiling file "/var/aw/var/LatexWiki/MYMON.NRLIB/MYMON.lsp" (written 25 DEC 2015 11:23:50 AM):
; /var/aw/var/LatexWiki/MYMON.NRLIB/MYMON.fasl written
; compilation finished in 0:00:00.016

MyMonoid is now explicitly exposed in frame initial
MyMonoid will be automatically loaded when needed from
/var/aw/var/LatexWiki/MYMON.NRLIB/MYMON Every constructor needs an )abbrev line where one specifies whether the constructor to come is
a category or domain. Then follows a capitalized identifier of at most 7 characters and finally
the identifier for the constructor.
By convention, constructors begin with an uppercase letter and capitalize the first letter
of each new word. Underscores are not commonly used.
Supposed the above code goes into a file mymonoid.spad , then this file can be compiled via:
)compile mymonoid.spad
inside a FriCAS session.
Now comes the corresponding domain definition.
spad )abbrev domain MYFUN MyFun
MyFun(S: SetCategory): MyMonoid with
coerce: (S > S) > %
coerce: % > (S > S)
elt: (%, S) > S
== add
Rep ==> S > S
rep x ==> (x@%) pretend None pretend Rep
per x ==> (x@Rep) pretend %
coerce(f: S > S): % == per f
coerce(x: %): S > S == rep x
elt(x: %, s: S): S == (rep x) s
1: % == per((s: S): S +> s)
((x: %) * (y: %)): % == per( (s: S): S +> x y s )
spad Compiling FriCAS source code from file
/var/lib/zope2.10/instance/axiomwiki/var/LatexWiki/520251930982853046025px002.spad
using old system compiler.
MYFUN abbreviates domain MyFun

initializing NRLIB MYFUN for MyFun
compiling into NRLIB MYFUN
processing macro definition Rep ==> S > S
processing macro definition rep x ==> pretend(pretend(@(x,$),None),S > S)
processing macro definition per x ==> pretend(@(x,S > S),$)
compiling exported coerce : S > S > $
MYFUN;coerce;M$;1 is replaced by f
Time: 0 SEC.
compiling exported coerce : $ > S > S
MYFUN;coerce;$M;2 is replaced by x
Time: 0 SEC.
compiling exported elt : ($,S) > S
MYFUN;elt;$2S;3 is replaced by SPADCALLsx
Time: 0 SEC.
compiling exported One : () > $
Time: 0 SEC.
compiling exported * : ($,$) > $
Time: 0 SEC.
(time taken in buildFunctor: 0)
;;; *** MyFun REDEFINED
;;; *** MyFun REDEFINED
Time: 0.01 SEC.
Cumulative Statistics for Constructor MyFun
Time: 0.01 seconds
finalizing NRLIB MYFUN
Processing MyFun for Browser database:
>>MyFun(constructor): Not documented!!!!
>>MyFun((coerce (% (Mapping S S)))): Not documented!!!!
>>MyFun((coerce ((Mapping S S) %))): Not documented!!!!
>>MyFun((elt (S % S))): Not documented!!!!
>>MyFun(): Missing Description
; compiling file "/var/aw/var/LatexWiki/MYFUN.NRLIB/MYFUN.lsp" (written 25 DEC 2015 11:23:50 AM):
; /var/aw/var/LatexWiki/MYFUN.NRLIB/MYFUN.fasl written
; compilation finished in 0:00:00.072

MyFun is now explicitly exposed in frame initial
MyFun will be automatically loaded when needed from
/var/aw/var/LatexWiki/MYFUN.NRLIB/MYFUN This above code for MyFun can be in the same file as the code for MyMonoid ,
then one compilation would be enough. If, however, it is in another file myfun.spad ,
then a call to:
)compile myfun.spad
inside a FriCAS session would be necessary.
Now we can use our little program. For that, we enter a FriCAS session and type the following.
fricas Z ==> Integer
Type: Void
fricas MZ ==> MyFun Z
Type: Void
fricas inc(z: Z): Z == z+1
Function declaration inc : Integer > Integer has been added to
workspace.
Type: Void
fricas double(z: Z): Z == 2*z
Function declaration double : Integer > Integer has been added to
workspace.
Type: Void
fricas minc := inc :: MZ
fricas Compiling function inc with type Integer > Integer
LISP output:
(#<FUNCTION *1;inc;1;initial>)
fricas mdouble := double :: MZ
fricas Compiling function double with type Integer > Integer
LISP output:
(#<FUNCTION *1;double;1;initial>)
fricas f := mdouble * minc;
fricas g := minc * mdouble;
fricas f 1
fricas g 1
Note that the multiplication is not commutative.
Comments on the above program
 SPAD distinguishes between
% and Rep .
That's the reason for the definition of rep and per before MyFun .
((Note that the pretend None pretend Rep is only there because we are
dealing with the domain S>S .
In general pretend Rep is enough.)) The percent sign is a name for the current domain, it is comparable to this or self
in other programming languages, but it does not denote the object, but rather its type,
i.e., % stands for a domain.
In the definition of MyFun , % basically stands for MyFun(S) .
In contrast to that, Rep denotes the domain that the current domain inherits its
data representation from (but not it's exports).
The distinction between % and Rep is in what they export.
Whereas % exports all the functions that are listed in the category part of the domain,
Rep points to a previously defined domain and thus exports exactly what is given there.
In our case Rep is the same as S > S . Whereas % exports * ,
Rep does not. In contrast to that. Rep allows to write f(s)
if f is of type S > S and s is of type S , i.e. one can apply f to
an argument of type S .
 The expression
x y s stands for x(y(s)) .
In other words, juxtaposition in FriCAS associates to the right and usually means
function application. Note, however, that x and y are of type %
and not of type S > S . SPAD comes with a special feature. If in some context the compiler sees an expression
a b with a of type A and b of type B , and there is a function
elt: (A, B) > C
then a b will be interpreted as elt(a, b) .
In other words, the definition of elt: (%, S) > S can be seen
as syntactic sugar.
 Similar to Python, instead of braces, SPAD uses indentation to group code blocks.
 The escape character in SPAD is an underscore, not a backslash.
Currently, the
* identifier in the definition of MyMonoid must be escaped in that position.
(There is hope that this need will go away in the future.)
 The symbol
1 in the definition of MyMonoid is not a number, but rather an identifier.
Since in mathematics, 0 and 1 are used so often, both can be used as identifiers.
 One usually writes
t: T to denote that t is of type T , i.e. with
_*: (%, %) > %
we declare that * is of type (%, %) > % .
The identifier > is a builtin type constructor.
Here it means that * is a function with two arguments, both of the same type,
which returns a result of that type.
SPAD defines a few binary operators, like '+', '*', rem , quo to be infix.
Except those few functions, all functions are used in prefix form, though.
 A category is defined by the following pattern
C: Category == Join(C1,...,Cn) with
f1: T1
...
fk: Tk
where Join(...) can be missing or just be a single category C1 .
 A domain is defined by the following pattern
D: C == A add
Rep ==> A
rep x ==> (x@%) pretend Rep
per x ==> (x@Rep) pretend %
f1: T1 == ...
...
fk: Tk == ...
where C is a category and A is a domain from which D inherits.
If a domain A appears in front of the add keyword, then D inherits
also all the implementations of the functions that are listed in the
category part C .
 SPAD has macros.
X ==> Y
macro X == Y
Both of the above lines are doing the same thing, they define a macro X that
expands to Y whenever it appears elsewhere in the program code.
Of course, only one of these lines would be sufficient.
Macros can have parameters.
 The notation
(s: S): S +> ....
is the SPAD way to denote lambda expressions (unnamed functions).
 The notation
x @ X means x will be of type X .
That is rarely seen in SPAD, but since SPAD not only allows to distinguish
functions by their input types, but also their output types, it is sometimes necessary. For example, in SPAD = is not builtin. It is an ordinary function of type
(%, %) > T
where T can be different things. For example, the domain Integer exports a function
_=: (%, %) > Boolean
with the usual meaning of equality. However, there is another domain in FriCAS, namely
Equation(Integer) that exports a function
_=: (Integer, Integer) > %
Now, without @ it would be impossible to tell what the type of
42 = 7
is. It could be Boolean or Equation(Integer) .
If the result should be of type Boolean , we write
(42 = 7)@Boolean
 The use of
pretend in t pretend X is very dangerous.
It tells the compiler to consider t as an element of type X even though it might
be of a type T with a completely different memory layout.
In other words "abc" pretend Integer would interpret the storage of "abc"
as an element of type Integer . Careless use of pretend usually leads to a program
crash and should thus better be avoided. Since % and Rep are supposed to have the same memory layout, pretend is safe in:
rep x ==> (x@%) pretend Rep
Nevertheless is pretend a way to make the safety that SPAD brings with its type system
void if it is not used with great care. In fact, pretend should be used only in these
rare situations where the compiler is unable to figure out the right type itself.
 The notation
t :: X is, in fact, equivalent to coerce(t)@X , i.e.
a function with name coerce is called to turn the element t (which might be of type T )
into an element of type X . In contrast to @ or pretend :: leads to
the execution of this coercion at runtime.
More information about SPAD can be found in the Axiom book .
See also simple Spad examples .
See also How does one program in the AXIOM System .
Note however, that this article is from 1992 actually describes
the system AXIOM , i.e., the system that FriCAS forked from.
Most of the text is still applicable.
Nowadays instead of the dollar symbol, one has to use a
percent sign to denote "current domain".
Since the Aldor programming language is very similar to SPAD,
it might be advantageous to read the Aldor User Guide .
There are, however, a number of differences between SPAD and Aldor .
Nevertheless, it is possible to use the Aldor compiler to program new functionality for FriCAS.
You might want to try out Aldor .
To try out SPAD online you simply edit a wiki Sandbox page and
put your code into \begin {spad} ... \end {spad} blocks.
Making the example a bit more complex
The above code shows the basic way how to define categories and domains.
Now we introduce inheritance and extend MyFun so that it becomes a structure
that satisfies the Monoid type as defined in the FriCAS library.
Now (for demo purposes) we are going to prefix our new domains by ZZ in
order to distinguish them from possibly existing names.
The FriCAS library already contains
a definition of a Monoid .
It's a bit richer than our MyMonoid from above, so we have to implement a few more
functions in ZZFun .
In particular, Monoid defines equality and output of elements.
Since we want to have coercions from and to this domain and also like
to include function application directly, we start with a category that collects
these functions.
spad )abbrev category ZZMON ZZMonoid
ZZMonoid(S: SetCategory): Category ==
Join(MyMonoid, CoercibleTo(S > S), CoercibleFrom(S > S)) with
elt: (%, S) > S
)abbrev category ZZFMON ZZFunMonoid
ZZFunMonoid(S: Finite): Category == Join(ZZMonoid S, Monoid)
)abbrev domain ZZFUN ZZFun
ZZFun(S: SetCategory): ZZMonoid S with
if S has Finite then ZZFunMonoid(S)
== MyFun S add
Rep ==> MyFun S
rep x ==> (x@%) pretend Rep
per x ==> (x@Rep) pretend %
if S has Finite then
elements: List S := enumerate()$S
((x: %) = (y: %)): Boolean ==
for s in elements repeat
if x s ~= y s then return false
true
coerce(x: %): OutputForm ==
of z ==> z::OutputForm
pairs: List OutputForm := [paren [of s, of x s] for s in elements]
bracket pairs
spad Compiling FriCAS source code from file
/var/lib/zope2.10/instance/axiomwiki/var/LatexWiki/135001348211860599325px004.spad
using old system compiler.
ZZMON abbreviates category ZZMonoid

initializing NRLIB ZZMON for ZZMonoid
compiling into NRLIB ZZMON
;;; *** ZZMonoid REDEFINED
Time: 0 SEC.
finalizing NRLIB ZZMON
Processing ZZMonoid for Browser database:
>>ZZMonoid(constructor): Not documented!!!!
>>ZZMonoid((elt (S % S))): Not documented!!!!
>>ZZMonoid(): Missing Description
; compiling file "/var/aw/var/LatexWiki/ZZMON.NRLIB/ZZMON.lsp" (written 25 DEC 2015 11:23:50 AM):
; /var/aw/var/LatexWiki/ZZMON.NRLIB/ZZMON.fasl written
; compilation finished in 0:00:00.007

ZZMonoid is now explicitly exposed in frame initial
ZZMonoid will be automatically loaded when needed from
/var/aw/var/LatexWiki/ZZMON.NRLIB/ZZMON
ZZFMON abbreviates category ZZFunMonoid

initializing NRLIB ZZFMON for ZZFunMonoid
compiling into NRLIB ZZFMON
;;; *** ZZFunMonoid REDEFINED
Time: 0 SEC.
finalizing NRLIB ZZFMON
Processing ZZFunMonoid for Browser database:
>>ZZFunMonoid(constructor): Not documented!!!!
>>ZZFunMonoid((elt (S % S))): Not documented!!!!
>>ZZFunMonoid(): Missing Description
; compiling file "/var/aw/var/LatexWiki/ZZFMON.NRLIB/ZZFMON.lsp" (written 25 DEC 2015 11:23:50 AM):
; /var/aw/var/LatexWiki/ZZFMON.NRLIB/ZZFMON.fasl written
; compilation finished in 0:00:00.003

ZZFunMonoid is now explicitly exposed in frame initial
ZZFunMonoid will be automatically loaded when needed from
/var/aw/var/LatexWiki/ZZFMON.NRLIB/ZZFMON
ZZFUN abbreviates domain ZZFun

initializing NRLIB ZZFUN for ZZFun
compiling into NRLIB ZZFUN
processing macro definition Rep ==> MyFun S
processing macro definition rep x ==> pretend(@(x,$),MyFun S)
processing macro definition per x ==> pretend(@(x,MyFun S),$)
****** Domain: S already in scope
augmenting S: (Finite)
compiling exported = : ($,$) > Boolean
Time: 0 SEC.
compiling exported coerce : $ > OutputForm
processing macro definition of z ==> ::(z,OutputForm)
Time: 0.01 SEC.
****** Domain: S already in scope
augmenting S: (Finite)
(time taken in buildFunctor: 0)
;;; *** ZZFun REDEFINED
;;; *** ZZFun REDEFINED
Time: 0 SEC.
Cumulative Statistics for Constructor ZZFun
Time: 0.01 seconds
finalizing NRLIB ZZFUN
Processing ZZFun for Browser database:
>>ZZFun(constructor): Not documented!!!!
>>ZZFun((elt (S % S))): Not documented!!!!
>>ZZFun(): Missing Description
; compiling file "/var/aw/var/LatexWiki/ZZFUN.NRLIB/ZZFUN.lsp" (written 25 DEC 2015 11:23:50 AM):
; /var/aw/var/LatexWiki/ZZFUN.NRLIB/ZZFUN.fasl written
; compilation finished in 0:00:00.073

ZZFun is now explicitly exposed in frame initial
ZZFun will be automatically loaded when needed from
/var/aw/var/LatexWiki/ZZFUN.NRLIB/ZZFUN
Comments on the above program
 Over an infinite domain
S , we cannot algorithmically decide whether two
functions from S into itself are equal or not.
For finite S , however, algorithmic equality testing is possible.
The same applies to printing.
We, therefore, allow for arguments of ZZFunMonoid only finite domains.
 The domain
ZZFun(S) , however, basically behaves like MyFun(S) if S is not
finite. In fact, the line
== MyFun S add
says that ZZFun(S) inherits the implementation from MyFun(S) .
Everything that comes after the add keyword either overrides some functions
from MyFun or implements new functionality.
 If, however, the parameter
S is finite, the number of exports is different.
In other words, ZZFun(Integer) and ZZFun(PrimeField 5) have different exports.
SPAD allows conditional exports as introduced via the line
if S has Finite then ZZFunMonoid(S)
for the category part (keyword with ) and via the line
if S has Finite then
(and the following lines) for the implementation part (keyword add ).
 The notation
foo() $ Dom
means to call function foo from domain Dom .
It is important
in two cases
 if the functions from domain
Dom have not been imported via
import from Dom
and thus foo would not be in scope, or
 if there are two functions
foo with the same signature in scope,
one from domain Dom and another from domain Baz .
Then $ Dom serves as disambiguator.
 The symbol
~= means not equal and is defined in
BasicType?
as the negation of = . Equality testing and printing is not available for ZZFun(Integer) .
fricas ZZZ ==> ZZFun Z
Type: Void
fricas zz1 := inc :: ZZZ
LISP output:
(#<FUNCTION *1;inc;1;initial>)
fricas zz2 := double :: ZZZ
LISP output:
(#<FUNCTION *1;double;1;initial>)
fricas (zz1 = zz2)@Boolean
There are 2 exposed and 7 unexposed library operations named =
having 2 argument(s) but none was determined to be applicable.
Use HyperDoc Browse, or issue
)display op =
to learn more about the available operations. Perhaps
packagecalling the operation or using coercions on the arguments
will allow you to apply the operation.
Cannot find a definition or applicable library operation named =
with argument type(s)
ZZFun(Integer)
ZZFun(Integer)
Perhaps you should use "@" to indicate the required return type,
or "$" to specify which version of the function you need.
 However, it is available for
ZZFun(PrimeField 5) .
fricas Z5 ==> PrimeField 5
Type: Void
fricas ZZ5 ==> ZZFun Z5
Type: Void
fricas inc5(z: Z5): Z5 == z+1
Function declaration inc5 : PrimeField(5) > PrimeField(5) has been
added to workspace.
Type: Void
fricas double5(z: Z5): Z5 == 2*z
Function declaration double5 : PrimeField(5) > PrimeField(5) has
been added to workspace.
Type: Void
fricas z51 := inc5 :: ZZ5
fricas Compiling function inc5 with type PrimeField(5) > PrimeField(5)
Type: ZZFun ?(PrimeField ?(5))
fricas z52 := double5 :: ZZ5
fricas Compiling function double5 with type PrimeField(5) > PrimeField(5)
Type: ZZFun ?(PrimeField ?(5))
fricas (z51 = z52)@Boolean
Type: Boolean
Having a monoid, we can, of course, also use it to form a monoid ring.
fricas P ==> MonoidRing(Z, ZZ5)
Type: Void
fricas p1: P := 2*z51  1
Type: MonoidRing ?(Integer, ZZFun?(PrimeField?(5)))
fricas p2: P := 3*z52^3 + 2
Type: MonoidRing ?(Integer, ZZFun?(PrimeField?(5)))
fricas p1*p2
Type: MonoidRing ?(Integer, ZZFun?(PrimeField?(5)))
