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RosettaStone
  
last edited 4 years ago by test1 

 1  Rosetta Translations




1.1  Introduction


The following is a collection of synonyms for various operations in
the computer algebra systems [FriCAS], [Derive], [GAP], [Gmp], DoCon,
[Macsyma], [Magnus], [Maxima], [Maple], [Mathematica], [MuPAD], [Octave],
[Pari], [Reduce], [Scilab], [Sumit] and [Yacas]. This collection does not
attempt to be comprehensive, but hopefully it will be useful in giving
an indication of how to translate between the syntaxes used by the
different systems in many common situations. Note that a blank entry
means either (a) that there may be an exact translation of a
particular operation for the indicated system, but we don't know what
it is or (b) there is no exact translation but it may still be
possible to work around this lack with a related functionality.



While commercial systems are not provided the intent of the
Rosetta effort is to make it possible for experienced Computer Algebra
users to experiment with other systems. Thus the commands for
commercial systems are included to allow users of those systems to
translate.



Some of these systems are special purpose and do not support a lot of
the functionality of the more general purpose systems. Where they do
support an interpreter the commands are provided.



Originally written by Michael Wester.
Modified for Rosetta by Timothy Daly, Alexander Hulpke (GAP).






1.2  System availability






System
License
Status
Web Location



Aldor
BSD
available
http://www.aldor.org



FriCAS
open source
avalilable
http://fricas.sf.net



Derive
commercial
defunct
http://www.mathware.com



DoCon
open source
available
http://www.haskell.org/docon



GAP
GPL
Rosetta
http://www.gap-system.org/



Gmp
GPL
Rosetta
http://www.swox.com/gmp



Macsyma
commercial
dead
unavailable



Magnus
GPL
Rosetta
http://zebra.sci.ccny.cuny.edu/web



Maxima
GPL
Rosetta
http://maxima.sourceforge.net/



Maple
commercial
available
http://www.maplesoft.com



Mathematica
commercial
available
http://www.wolfram.com



MuPAD
commercial
defunct, available as Matlab toolkit
http://www.mupad.de



Octave
GPL
Rosetta
http://www.octave.org



Pari
GPL
Rosetta
http://www.parigp-home.de



Reduce
BSD
available
http://www.zib.de/Symbolik/reduce



Scilab
Scilab
available
http://www-rocq.inria.fr/scilab



Sumit
 
available
http://www-sop.inria.fr/cafe/soft-f.html



Yacas
GPL
available
http://yacas.sourceforge.net

 






System
Type
Interpreted or Compiled



FriCAS
General Purpose
both



Derive
General Purpose
 



DoCon
General Purpose
Compiled in Haskell



GAP
Group Theory
 



Gmp
arb. prec. arithmetic
 



Macsyma
General Purpose
 



Magnus
Infinite Group Theory
 



Maxima
General Purpose
 



Maple
General Purpose
 



Mathematica
General Purpose
 



MuPAD
General Purpose
 



Octave
Numerical Computing
 



Pari
Number Theory
 



Reduce
General Purpose
 



Scilab
General Purpose
 



Sumit
Functional Equations
 



Yacas
General Purpose
 

 




1.3  Programming and Miscellaneous







 
Unix/Microsoft user initialization file



FriCAS
~/fricas.input
 



GAP
~/.gaprc
GAP.RC



Gmp
 
 



DoCon
 
 



Derive
 
derive.ini



Macsyma
~/macsyma-init.macsyma
mac-init.mac



Magnus
 
 



Maxima
~/macsyma-init.macsyma
mac-init.mac



Maple
~/.mapleinit
maplev5.ini



Mathematica
~/init.m
init.m



MuPAD
~/.mupad/userinit.mu
      \mupad\bin\userinit.mu



Octave
 
 



Pari
 
 



Reduce
~/.reducerc
reduce.rc



Scilab
 
 



Sumit
 
 



Yacas
 
 






 
Describe keyword
Find keywords containing pattern



FriCAS
 
)what operations pattern



Derive
 
 



DoCon
 
 



GAP
?keyword
??keyword



Gmp
 
 



Macsyma
describe("keyword")$
apropos("pattern");



Magnus
 
 



Maxima
describe("keyword")$
apropos("pattern");



Maple
?keyword
?pattern 1



Mathematica
?keyword
?pattern



MuPAD
?keyword
?pattern



Octave
help -i keyword
 



Pari
 
 



Reduce
 
 



Scilab
 
 



Sumit
 
 



Yacas
 
 








 
 
 
 
Prev.
Case
Variables



 
Comment
 
Line continuation
expr.
sensitive
assumed
        



FriCAS
-- comment
 
input _<CR>input
%
Yes
real



Derive
"comment"
 
input ~<CR>input
 
No
real



DoCon
 
 
 
 
 
 



GAP
# comment
 
input\<CR>input
last
Yes
no assumption



Gmp
 
 
 
 
 
 



Macsyma
/ comment /
 
input<CR>input;
%
No
real



Magnus
 
 
 
 
 
 



Maxima
/ comment /
 
input<CR>input;
%
No
real



Maple
# comment
 
input<CR>input;
%
Yes
complex



Mathematica
( comment )
 
input<CR>input
%
Yes
complex



MuPAD
/ comment / or // comment
 
input<CR>input;
%
Yes
complex



Octave
##
 
 
 
Yes
 



Pari
 
 
 
 
 
 



Reduce
% comment
 
input<CR>input;
ws
No
complex



Scilab
 
 
 
 
 
 



Sumit
 
 
 
 
 
 



Yacas
 
 
 
 
 
 






 
Load a file
Time a command
Quit



FriCAS
)read "file" )quiet
)set messages time on
)quit



Derive
[Transfer Load Derive]
 
[Quit]



DoCon
 
 
 



GAP
Read("file");
time; (also see Runtime();)
quit;



Gmp
 
 
 



Macsyma
load("file")$
showtime: all$
quit();



Magnus
 
 
 



Maxima
load("file")$
showtime: all$
quit();



Maple
read("file"):
readlib(showtime): on;
quit



Mathematica
<< file
Timing[command]
Quit[]



MuPAD
read("file"):
time(command);
quit



Octave
load file
tic(); cmd ; toc()
quit or  exit



Pari
 
 
 



Reduce
in "file"$
on time;
quit;



Scilab
 
 
quit



Sumit
 
 
 



Yacas
 
 
 






 
Display
Suppress
 



 
output
output
Substitution: f(x, y) ® f(z, w)



FriCAS
input
input;
subst(f(x, y), [x = z, y = w])



Derive
input
var:= input
[Manage Substitute]



DoCon
 
 
 



GAP
input;
input;;
Value(f,[x,y],[z,w]);2



Gmp
 
 
 



Macsyma
input;
input$
subst([x = z, y = w], f(x, y));



Magnus
 
 
 



Maxima
input;
input$
subst([x = z, y = w], f(x, y));



Maple
input;
input:
subs({x = z, y = w}, f(x, y));



Mathematica
input
input;
f[x, y] /. {x -> z, y -> w}



MuPAD
input;
input:
subs(f(x, y), [x = z, y = w]);



Octave
input
input;
 



Pari
 
 
 



Reduce
input;
input$
sub({x = z, y = w}, f(x, y));



Scilab
 
 
 



Sumit
 
 
 



Yacas
 
 
 






 
Set
List
Matrix



FriCAS
set [1, 2]
[1, 2]
matrix([[1, 2],[3, 4]])



Derive
{1, 2}
[1, 2]
[[1,2], [3,4]]



DoCon
 
 
 



GAP
Set([1,2])
[1, 2]
[[1,2], [3,4]]3



Gmp
 
 
 



Macsyma
[1, 2]
[1, 2]
matrix([1, 2], [3, 4])



Magnus
 
 
 



Maxima
[1, 2]
[1, 2]
matrix([1, 2], [3, 4])



Maple
{1, 2}
[1, 2]
matrix([[1, 2], [3, 4]])



Mathematica
{1, 2}
{1, 2}
{{1, 2}, {3, 4}}



MuPAD
{1, 2}
[1, 2]
matrix([![1, 2], [3, 4]])



Octave
 
 
 



Pari
 
 
 



Reduce
{1, 2}
{1, 2}
mat((1, 2), (3, 4))



Scilab
 
list(1,2)
A=[1,2;3,4]



Sumit
 
 
 



Yacas
 
 
 






 
Equation
List element
Matrix element
Length of a list



FriCAS
x = 0
l . 2
m(2, 3)
#l



Derive
x = 0
l SUB 2
m SUB 2 SUB 3
DIMENSION(l)



DoCon
 
 
 
 



GAP
x=0
l[2]
m[2][3]
Length(l)



Gmp
 
 
 
 



Macsyma
x = 0
l[2]
m[2, 3]
length(l)



Magnus
 
 
 
 



Maxima
x = 0
l[2]
m[2, 3]
length(l)



Maple
x = 0
l[2]
m[2, 3]
nops(l)



Mathematica
x == 0
l[[2]]
m[[2, 3]]
Length[l]



MuPAD
x = 0
l[2]
m[2, 3]
nops(l)



Octave
 
 
 
 



Pari
 
 
 
 



Reduce
x = 0
part(l, 2)
m(2, 3)
length(l)



Scilab
 
l(2)
 
 



Sumit
 
 
 
 



Yacas
 
 
 
 






 
Prepend/append an element to a list
Append two lists



FriCAS
cons(e, l)
concat(l, e)
append(l1, l2)



Derive
APPEND([e], l)
APPEND(l, [e])
APPEND(l1, l2)



DoCon
 
 
 



GAP
Concatenation([e],l)
Add(l,e)
Append(l1, l2)



Gmp
 
 
 



Macsyma
cons(e, l)
endcons(e, l)
append(l1, l2)



Magnus
 
 
 



Maxima
cons(e, l)
endcons(e, l)
append(l1, l2)



Maple
[e, op(l)]
[op(l), e]
[op(l1), op(l2)]



Mathematica
Prepend[l, e]
Append[l, e]
Join[l1, l2]



MuPAD
[e] . l
append(l, e)
l1 . l2



Octave
 
 
 



Pari
 
 
 



Reduce
e . l
append(l, e)
append(l1, l2)



Scilab
 
 
 



Sumit
 
 
 



Yacas
 
 
 






 
Matrix column dimension
Convert a list into a column vector



FriCAS
ncols(m)
transpose(matrix([l]))



Derive
DIMENSION(m SUB 1)
[l]`



DoCon
 
 



GAP
Length(mat[1])
objects are identical



Gmp
 
 



Macsyma
mat_ ncols(m)
transpose(matrix(l))



Magnus
 
 



Maxima
mat_ ncols(m)
transpose(matrix(l))



Maple
linalg[coldim](m)
linalg[transpose](matrix([l]))



Mathematica
Dimensions[m][[2]]
Transpose[{l}]



MuPAD
linalg::ncols(m)
linalg::transpose(matrix([l])) 



Octave
 
 



Pari
 
 



Reduce
load_ package(linalg)$
matrix v(length(l), 1)$



 
column_dim(m)
for i:=1:length(l) do



 
 
    v(i, 1):= part(l, i)



Scilab
 
 



Sumit
 
 



Yacas
 
 








 
Convert a column vector into a list



FriCAS
parts(v)



Derive
v` SUB 1



DoCon
 



GAP
objects are identical



Gmp
 



Macsyma
part(transpose(v), 1)



Magnus
 



Maxima
part(transpose(v), 1)



Maple
op(convert(linalg[transpose](v), listlist))



Mathematica
Flatten[v]



MuPAD
[op(v)]



Octave
 



Pari
 



Reduce
load_ package(linalg)$



 
for i:=1:row_ dim(v) collect(v(i, 1))



Scilab
 



Sumit
 



Yacas
 






 
True
False
And
Or
Not
Equal
Not equal
        



FriCAS
true
false
and
or
not
=
~=



Derive
TRUE
FALSE
AND
OR
NOT
=
/=



DoCon
 
 
 
 
 
 
 



GAP
true
false4
and
or
not
=
<>



Gmp
 
 
 
 
 
 
 



Macsyma
true
false
and
or
not
=
#



Magnus
 
 
 
 
 
 
 



Maxima
true
false
and
or
not
=
#



Maple
true
false
and
or
not
=
<>



Mathematica
True
False
&&
||
!
==
!=



MuPAD
TRUE
FALSE
and
or
not
=
<>



Octave
 
 
 
 
 
 
 



Pari
 
 
 
 
 
 
 



Reduce
t
nil
and
or
not
=
neq



Scilab
%t
%f
 
 
 
 
 



Sumit
 
 
 
 
 
 
 



Yacas
 
 
 
 
 
 
 






 
If+then+else statements
Strings (concatenated)



FriCAS
if  then  else if  then  else _
concat(["x", "y"])



Derive
IF(, , IF(, , _))
"xy"



DoCon
 
 



GAP
if  then  elif  then  else _ fi
Concatenation("x","y")



Gmp
 
 



Macsyma
if  then  else if  then  else _
concat("x", "y")



Magnus
 
 



Maxima
if  then  else if  then  else _
concat("x", "y")



Maple
if  then  elif  then  else _ fi
"x" . "y"



Mathematica
[, , If![, , _][, , If![, , _]]
"x" <> "y"



MuPAD
if  then  elif  then  else _
"x" . "y"



 
    end_if
 



Octave
 
 



Pari
 
 



Reduce
if  then  else if  then  else _
"xy" or  mkid(x, y)



Scilab
 
 



Sumit
 
 



Yacas
 
 






 
Simple loop and Block
Generate the list [1, 2, ..., n]



FriCAS
for i in 1..n repeat ( x; y )
[f(i) for i in 1..n]



Derive
VECTOR([x, y], i, 1, n)
VECTOR(f(i), i, 1, n)



DoCon
 
 



GAP
for i in [1..n] do _ od;
[1..n] or [1,2..n]



Gmp
 
 



Macsyma
for i:1 thru n do (x, y);
makelist(f(i), i, 1, n);



Magnus
 
 



Maxima
for i:1 thru n do (x, y);
makelist(f(i), i, 1, n);



Maple
for i from 1 to n do x; y od;
[f(i) $ i = 1..n];



Mathematica
Do[x; y, {i, 1, n}]
Table[f[i], {i, 1, n}]



MuPAD
for i from 1 to n do x; y
[f(i) $ i = 1..n];



 
    end_for;
 



Octave
 
 



Pari
 
 



Reduce
for i:=1:n do <<x; y>>;
for i:=1:n collect f(i);



Scilab
 
 



Sumit
 
 



Yacas
 
 






 
Complex loop iterating on a list



FriCAS
for x in [2, 3, 5] while x^2 < 10 repeat output(x)



Derive
 



DoCon
 



GAP
for x in [2, 3, 5] do while x^2<10 do Print(x);od;od;



Gmp
 



Macsyma
for x in [2, 3, 5] while x^2 < 10 do print(x)$



Magnus
 



Maxima
for x in [2, 3, 5] while x^2 < 10 do print(x)$



Maple
for x in [2, 3, 5] while x^2 < 10 do print(x) od:



Mathematica
For[l = {2, 3, 5}, l != {} && l[[1]]^2 < 10,



 
  l = Rest[l], Print[l[[1]]] ]



MuPAD
for x in [2, 3, 5] do if x^2 < 10 then print(x) end_if



 
  end_for:



Octave
 



Pari
 



Reduce
for each x in {2, 3, 5} do if x^2 < 10 then write(x)$



Scilab
 



Sumit
 



Yacas
 






 
Assignment
Function definition
Clear vars and funs



FriCAS
y:= f(x)
f(x, y) == x*y
      )clear properties y f



Derive
y:= f(x)
f(x, y):= x*y
y:= f:=



DoCon
 
 
 



GAP
y:= f(x);
f:=function(x, y) return x*y; end;
There are
no symbolic variables



Gmp
 
 
 



Macsyma
y: f(x);
f(x, y):= x*y;
remvalue(y)$



 
 
 
remfunction(f)$



Magnus
 
 
 



Maxima
y: f(x);
f(x, y):= x*y;
remvalue(y)$



 
 
 
remfunction(f)$



Maple
y:= f(x);
f:= proc(x, y) x*y end;
y:= 'y': f:= 'f':



Mathematica
y = f[x]
f[x, y ]:= x*y
Clear[y, f]



MuPAD
y:= f(x)
(x, y) -> x*y
delete y, f



 
 
f:= proc(x, y)
 



 
 
    begin x*y end_proc
 



Octave
 
 
 



Pari
 
 
 



Reduce
y:= f(x);
procedure f(x, y); x*y;
clear y, f;



Scilab
 
 
 



Sumit
 
 
 



Yacas
 
 
 






 
Function definition with a local variable



FriCAS
f(x) == (local n; n:= 2; n*x)



Derive
 



DoCon
 



GAP
f:=function(x) local n; n:=2;return n*x; end;



Gmp
 



Macsyma
f(x):= block([n], n: 2, n*x);



Magnus
 



Maxima
f(x):= block([n], n: 2, n*x);



Maple
f:= proc(x) local n; n:= 2; n*x end;



Mathematica
f[x_ ]:= Module[{n}, n = 2; n*x]



MuPAD
f:= proc(x) local n; begin n:= 2; n*x end_proc;



Octave
 



Pari
 



Reduce
procedure f(x); begin scalar n; n:= 2; return(n*x) end;



Scilab
 



Sumit
 



Yacas
 






 
Return unevaluated symbol
Define a function from an expression



FriCAS
e:= x*y;  'e
function(e, f, x, y)



Derive
e:= x*y  'e
f(x, y):== e



DoCon
 
 



GAP
No unevaluated symbols6
 



Gmp
 
 



Macsyma
e: x*y$  'e;
define(f(x, y), e);



Magnus
 
 



Maxima
e: x*y$  'e;
define(f(x, y), e);



Maple
e:= x*y:  'e';
f:= unapply(e, x, y);



Mathematica
e = x*y;  HoldForm[e]
f[x, y ] = e



MuPAD
e:= x*y:  hold(e);
f:= hold(func)(e, x, y);



Octave
 
 



Pari
 
 



Reduce
e:= x*y$
for all x, y let f(x, y):= e;



Scilab
 
 



Sumit
 
 



Yacas
 
 









 
Fun. of an indefinite number of args
Apply ``+'' to sum a list



FriCAS
 
reduce(+, [1, 2])



Derive
LST l:= l
 



DoCon
 
 



GAP
lst:=function(args) _ end;
Sum([1,2])



Gmp
 
 



Macsyma
lst([l]):= l;
apply("+", [1, 2])



Magnus
 
 



Maxima
lst([l]):= l;
apply("+", [1, 2])



Maple
lst:=proc() [args[1..nargs]] end;
convert([1, 2], `+`)



Mathematica
lst[l  _ ]:= {l}
Apply[Plus, {1, 2}]



MuPAD
lst:= proc() begin [args()]
_plus(op([1, 2]))



 
      end_ proc;
 



Octave
 
 



Pari
 
 



Reduce
 
xapply(+, {1, 2}) 5



Scilab
 
 



Sumit
 
 



Yacas
 
 









 
Apply a fun. to a
 



 
list of its args
Map an anonymous function onto a list



FriCAS
reduce(f, l)
map(x +-> x + y, [1, 2])



Derive
 
x:= [1, 2]



 
 
VECTOR(x SUB i + y, i, 1, DIMENSION(x))



DoCon
 
 



GAP
List(l,f)
List([1,2],x->x+y)



Gmp
 
 



Macsyma
apply(f, l)
map(lambda([x], x + y), [1, 2])



Magnus
 
 



Maxima
apply(f, l)
map(lambda([x], x + y), [1, 2])



Maple
f(op(l))
map(x -> x + y, [1, 2])



Mathematica
Apply[f, l]
Map[# + y &, {1, 2}]



MuPAD
f(op(l))
map([1, 2], x -> x + y)



Octave
 
 



Pari
 
 



Reduce
xapply(f, l) 6
for each x in {1, 2} collect x + y



Scilab
 
 



Sumit
 
 



Yacas
 
 






 
Pattern matching: f(3 y) + f(z y) ® 3 f(y) + f(z y)



FriCAS
f:= operator('f);



 
( rule f((n | integer?(n))  x) == nf(x) )( _



 
    f(3y) + f(zy))



Derive
 



DoCon
 



GAP
 



Gmp
 



Macsyma
matchdeclare(n, integerp, x, true)$



 
defrule(fnx, f(nx), nf(x))$



 
apply1(f(3y) + f(zy), fnx);



Magnus
 



Maxima
matchdeclare(n, integerp, x, true)$



 
defrule(fnx, f(nx), nf(x))$



 
apply1(f(3y) + f(zy), fnx);



Maple
map(proc(q) local m;



 
      if match(q = f(n*y), y, m) and



 
          type(rhs(op(m)), integer) then



 
        subs(m, n * f(y)) else q fi



 
    end,



 
    f(3y) + f(zy));



Mathematica
f[3*y] + f[z*y] /. f[n_Integer  x_ ] -> nf[x]



MuPAD
 



Octave
 



Pari
 



Reduce
operator f;



 
f(3y) + f(zy)



 
    where {f(~n  ~x) => nf(x) when fixp(n)};



Scilab
 



Sumit
 



Yacas
 






 
Define a new infix operator and then use it



FriCAS
 



Derive
 



DoCon
 



GAP
One can overload existing infix operators for ones own purposes



Gmp
 



Macsyma
infix("~")$   "~"(x, y):= sqrt(x^2 + y^2)$        3 ~ 4;



Magnus
 



Maxima
infix("~")$   "~"(x, y):= sqrt(x^2 + y^2)$        3 ~ 4;



Maple
`&~`:= (x, y) -> sqrt(x^2 + y^2):   3 &~ 4;
        



Mathematica
x_ \[Tilde] y_:= Sqrt[x^2 + y^2];           3 \[Tilde] 4



MuPAD
tilde:= proc(x, y) begin sqrt(x^2 + y^2) end_ proc:



 
  operator("~", tilde, Binary, 100):



 
  3 ~ 4;



Octave
 



Pari
 



Reduce
infix |$   procedure |(x, y); sqrt(x^2 + y^2)$    3 | 4;



Scilab
 



Sumit
 



Yacas
 






 
Main expression
 
 



 
operator
11 th st nd rd operand
List of expression operands



FriCAS7
 
kernels(e) . 1
kernels(e)



Derive
 
 
various8



DoCon
 
 
 



GAP
There are no formal unevaluated expressions



Gmp
 
 
 



Macsyma
part(e, 0)
part(e, 1)
args(e)



Magnus
 
 
 



Maxima
part(e, 0)
part(e, 1)
args(e)



Maple
op(0, e)
op(1, e)
[op(e)]



Mathematica
Head[e]
e[[1]]
ReplacePart[e, List, 0]



MuPAD
op(e, 0)
op(e, 1)
[op(e)]



Octave
 
 
 



Pari
 
 
 



Reduce
part(e, 0)
part(e, 1)
for i:=1:arglength(e)



 
 
 
    collect part(e, i)



Scilab
 
 
 



Sumit
 
 
 



Yacas
 
 
 









 
Print text and results



FriCAS
output(concat(["sin(", string(0), ") = ",



 
  string(sin(0))]));



Derive
"sin(0)" = sin(0)



DoCon
 



GAP
Print("There is no sin, but factors(10)= ",Factors(10),
"\n")



Gmp
 



Macsyma
print("sin(", 0, ") =", sin(0))$



Magnus
 



Maxima
print("sin(", 0, ") =", sin(0))$



Maple
printf("sin(%a) = %a\n", 0, sin(0)):



Mathematica
Print[StringForm["sin(``) = ``", 0, Sin[0]]];



MuPAD
print(Unquoted, "sin(".0.")" = sin(0)):



Octave
 



Pari
 



Reduce
write("sin(", 0, ") = ", sin(0))$



Scilab
 



Sumit
 



Yacas
 






 
Generate FORTRAN
Generate TeX/LATEX



FriCAS
outputAsFortran(e)
outputAsTex(e)



Derive
[Transfer Save Fortran]
 



DoCon
 
 



GAP
 
Print(LaTeX(e));



Gmp
 
 



Macsyma
fortran(e)$ or gentran(eval(e))$
tex(e);



Magnus
 
 



Maxima
fortran(e)$ or gentran(eval(e))$
tex(e);



Maple
fortran([e]);
latex(e);



Mathematica
FortranForm[e]
TexForm[e]



MuPAD
generate::fortran(e);
generate::TeX(e);



Octave
 
 



Pari
 
 



Reduce
on fort;   e;   off fort; or 
load_ package(tri)$



 
load_ package(gentran)$ gentran e;
on TeX; e; off TeX;



Scilab
 
 



Sumit
 
 



Yacas
 
 






 
Import two space separated columns of integers from file



FriCAS
 



Derive
[Transfer Load daTa] (from file.dat)



DoCon
 



GAP
 



Gmp
 



Macsyma
xy: read_num_data_to_matrix("file", nrows, 2)$



Magnus
 



Maxima
xy: read_num_data_to_matrix("file", nrows, 2)$



Maple
xy:= readdata("file", integer, 2):



Mathematica
xy = ReadList["file", Number, RecordLists -> True]



MuPAD
data := import::readdata("file")



Octave
 



Pari
 



Reduce
 



Scilab
 



Sumit
 



Yacas
 






 
Export two space separated columns of integers to file7



FriCAS
)set output algebra "file"   (creates file.spout)



 
for i in 1..n repeat output( _



 
  concat([string(xy(i, 1)), " ", string(xy(i, 2))]) )



 
)set output algebra console



Derive
xy [Transfer Print Expressions File]  (creates file.prt)



DoCon
 



GAP
PrintTo("file");for i in [1..n] do



 
  AppendTo("file",xy[i][1]," ",xy[i][2],"\n");od;



Gmp
 



Macsyma
writefile("file")$   for i:1 thru n do



 
  print(xy[i, 1], xy[i, 2])$   closefile()$



Magnus
 



Maxima
writefile("file")$   for i:1 thru n do



 
  print(xy[i, 1], xy[i, 2])$   closefile()$



Maple
writedata("file", xy);



Mathematica
outfile = OpenWrite["file"];



 
Do[WriteString[outfile,



 
  xy[[i, 1]], " ", xy[[i, 2]], "\n"], {i, 1, n}]



 
Close[outfile];



MuPAD
fprint(Unquoted, Text, "file",



 
  (xy[i, 1], " ", xy[i, 2], "\n") $ i = 1..n):



Octave
 



Pari
 



Reduce
out "file";   for i:=1:n do



 
  write(xy(i, 1), " ", xy(i, 2));   shut "file";



Scilab
 



Sumit
 



Sumit
 



Yacas
 










1.4  Mathematics and Graphics


Since GAP aims at discrete mathematics, it does not provide much of
the calculus functionality listed in the following section.




 
e
p
i
+Â¥
2
21/3



FriCAS
%e
%pi
%i
%plusInfinity
sqrt(2)
2^(1/3)



Derive
#e
pi
#i
inf
SQRT(2)
2^(1/3)



DoCon
 
 
 
 
 
 



GAP
 
 
E(4)
infinity
ER(2)8
 



Gmp
 
 
 
 
 
 



Macsyma
%e
%pi
%i
inf
sqrt(2)
2^(1/3)



Magnus
 
 
 
 
 
 



Maxima
%e
%pi
%i
inf
sqrt(2)
2^(1/3)



Maple
exp(1)
Pi
I
infinity
sqrt(2)
2^(1/3)



Mathematica
E
Pi
I
Infinity
Sqrt[2]
2^(1/3)



MuPAD
E
PI
I
infinity
sqrt(2)
2^(1/3)



Octave
 
 
 
 
 
 



Pari
 
 
 
 
 
 



Reduce
e
pi
i
infinity
sqrt(2)
2^(1/3)



Scilab
 
 
 
 
 
 



Sumit
 
 
 
 
 
 



Yacas
 
 
 
 
 
 









 
Euler's constant
Natural log
Arctangent
n!



FriCAS
 
log(x)
atan(x)
factorial(n)



Derive
euler_ gamma
LOG(x)
ATAN(x)
n!



DoCon
 
 
 
 



GAP
 
LogInt(x,base)
 
Factorial(n)



Gmp
 
 
 
 



Macsyma
%gamma
log(x)
atan(x)
n!



Magnus
 
 
 
 



Maxima
%gamma
log(x)
atan(x)
n!



Maple
gamma
log(x)
arctan(x)
n!



Mathematica
EulerGamma
Log[x]
ArcTan[x]
n!



MuPAD
EULER
ln(x)
atan(x)
n!



Octave
 
 
 
 



Pari
 
 
 
 



Reduce
Euler_ Gamma
log(x)
atan(x)
factorial(n)



Scilab
 
 
 
 



Sumit
 
 
 
 



Yacas
 
 
 
 






 
Legendre polynomial
Chebyshev poly. of the 11 th st nd rd kind



FriCAS
legendreP(n, x)
chebyshevT(n, x)



Derive
LEGENDRE_ P(n, x)
CHEBYCHEV_ T(n, x)



DoCon
 
 



GAP
 
 



Gmp
 
 



Macsyma
legendre_ p(n, x)
chebyshev_ t(n, x)



Magnus
 
 



Maxima
legendre_ p(n, x)
chebyshev_ t(n, x)



Maple
orthopoly[P](n, x)
orthopoly[T](n, x)



Mathematica
LegendreP[n, x]
ChebyshevT[n, x]



MuPAD
orthpoly::legendre(n, x)
orthpoly::chebyshev1(n, x)



Octave
 
 



Pari
 
 



Reduce
LegendreP(n, x)
ChebyshevT(n, x)



Scilab
 
 



Sumit
 
 



Yacas
 
 






 
Fibonacci number
Elliptic integral of the 11 th st nd rd kind



FriCAS
fibonacci(n)
ellipticE(sin(phi), k)



Derive
FIBONACCI(n)
ELLIPTIC_ E(phi, k^2)



DoCon
 
 



GAP
Fibonacci(n)
 



Gmp
 
 



Macsyma
fib(n)
elliptic_ e(phi, k^2)



Magnus
 
 



Maxima
fib(n)
elliptic_ e(phi, k^2)



Maple
combinat[fibonacci](n)
EllipticE(sin(phi), k)



Mathematica
Fibonacci[n]
EllipticE[phi, k^2]



MuPAD
numlib::fibonacci(n)
 



Octave
 
 



Pari
 
 



Reduce
 
EllipticE(phi, k^2)



Scilab
 
 



Sumit
 
 



Yacas
 
 






 
G(x)
y(x)
Cosine integral
Bessel fun. (11 th st nd rd)



FriCAS
Gamma(x)
psi(x)
Ci(x))
besselJ(n, x)



Derive
GAMMA(x)
PSI(x)
CI(x)
BESSEL_ J(n, x)



DoCon
 
 
 
 



GAP
 
 
 
 



Gmp
 
 
 
 



Macsyma
gamma(x)
psi[0](x)
cos_ int(x)
bessel_j[n](x)



Magnus
 
 
 
 



Maxima
gamma(x)
psi[0](x)
cos_ int(x)
bessel_j[n](x)



Maple
GAMMA(x)
Psi(x)
Ci(x)
BesselJ(n, x)



Mathematica
Gamma[x]
PolyGamma[x]
CosIntegral[x]
BesselJ[n, x]



MuPAD
gamma(x)
psi(x)
Ci(x)
besselJ(n, x)



Octave
 
 
 
 



Pari
 
 
 
 



Reduce
Gamma(x)
Psi(x)
Ci(x)
BesselJ(n, x)



Scilab
 
 
 
 



Sumit
 
 
 
 



Yacas
 
 
 
 






 
Hypergeometric fun. 2F1(a, b; c; x)
Dirac delta
      Unit step fun.



FriCAS
hypergeometricF([a, b], [c], x)
 
 



Derive
GAUSS(a, b, c, x)
 
STEP(x)



DoCon
 
 
 



GAP
 
 
 



Gmp
 
 
 



Macsyma
hgfred([a, b], [c], x)
delta(x)
unit_ step(x)
        



Magnus
 
 
 



Maxima
hgfred([a, b], [c], x)
delta(x)
unit_ step(x)
        



Maple
hypergeom([a, b], [c], x)
Dirac(x)
Heaviside(x)



Mathematica
HypergeometricPFQ[{a,b},{c},x]
<< Calculus`DiracDelta`



MuPAD
hypergeom([a,b], [c], x)
dirac(x)
heaviside(x)



Octave
 
 
 



Pari
 
 
 



Reduce
hypergeometric({a, b}, {c}, x)
 
 



Scilab
 
 
 



Sumit
 
 
 



Yacas
 
 
 






 
Define |x| via a piecewise function



FriCAS
 



Derive
a(x):= -xCHI(-inf, x, 0) + xCHI(0, x, inf)



DoCon
 



GAP
 



Gmp
 



Macsyma
a(x):= -xunit_ step(-x) + xunit_ step(x)$



Magnus
 



Maxima
a(x):= -xunit_ step(-x) + xunit_ step(x)$



Maple
a:= x -> piecewise(x < 0, -x, x):



Mathematica
<< Calculus`DiracDelta`



 
a[x_]:= -x*UnitStep[-x] + x*UnitStep[x]



MuPAD
a:= x -> piecewise([x<0, -x], [x>=0, x])



 
    end_ proc:



Octave
 



Pari
 



Reduce
 



Scilab
 



Sumit
 



Yacas
 






 
Assume x is real
Remove that assumption



FriCAS
 
 



Derive
x :epsilon Real
x:=



DoCon
 
 



GAP
 
 



Gmp
 
 



Macsyma
declare(x, real)$
remove(x, real)$



Magnus
 
 



Maxima
declare(x, real)$
remove(x, real)$



Maple
assume(x, real);
x:= 'x':



Mathematica
x/: Im[x] = 0;
Clear[x]



MuPAD
assume(x, Type::Real):
delete x:



Octave
 
 



Pari
 
 



Reduce
 
 



Scilab
 
 



Sumit
 
 



Yacas
 
 






 
Assume 0 < x £ 1
Remove that assumption



FriCAS
 
 



Derive
x :epsilon (0, 1]
x:=



DoCon
 
 



GAP
 
 



Gmp
 
 



Macsyma
assume(x > 0, x <= 1)$
forget(x > 0, x <= 1)$



Magnus
 
 



Maxima
assume(x > 0, x <= 1)$
forget(x > 0, x <= 1)$



Maple
assume(x > 0);
x:= 'x':



 
additionally(x <= 1);
 



Mathematica
Assumptions -> 0 < x <= 1 8
 



MuPAD
assume(0 < x <= 1):
delete x:



Octave
 
 



Pari
 
 



Reduce
 
 



Scilab
 
 



Sumit
 
 



Yacas
 
 








 
Basic simplification of an expression e



FriCAS
simplify(e) or  normalize(e) or  complexNormalize(e)



Derive
e



DoCon
 



GAP
e



Gmp
 



Macsyma
ratsimp(e) or  radcan(e)



Magnus
 



Maxima
ratsimp(e) or  radcan(e)



Maple
simplify(e)



Mathematica
Simplify[e] or  FullSimplify[e]



MuPAD
simplify(e) or  normal(e)



Octave
 



Pari
 



Reduce
e



Scilab
 



Sumit
 



Yacas
 






 
Use an unknown function
Numerically evaluate an expr.



FriCAS
f:= operator('f);   f(x)
exp(1) :: Complex Float



Derive
f(x):=
Precision:= Approximate



 
f(x)
APPROX(EXP(1))



 
 
Precision:= Exact



DoCon
 
 



GAP
 
EvalF(123/456)



Gmp
 
 



Macsyma
f(x)
sfloat(exp(1));



Magnus
 
 



Maxima
f(x)
sfloat(exp(1));



Maple
f(x)
evalf(exp(1));



Mathematica
f[x]
N[Exp[1]]



MuPAD
f(x)
float(exp(1));



Octave
 
 



Pari
 
 



Reduce
operator f;   f(x)
on rounded;   exp(1);



 
 
off rounded;



Scilab
 
 



Sumit
 
 



Yacas
 
 






 
n modm
Solve e º 0 modm for x



FriCAS
rem(n, m)
solve(e = 0 :: PrimeField(m), x)



Derive
MOD(n, m)
SOLVE_ MOD(e = 0, x, m)



DoCon
 
 



GAP
n mod m
solve using finite fields



Gmp
 
 



Macsyma
mod(n, m)
modulus: m$   solve(e = 0, x)



Magnus
 
 



Maxima
mod(n, m)
modulus: m$   solve(e = 0, x)



Maple
n mod m
msolve(e = 0, m)



Mathematica
Mod[n, m]
Solve[{e == 0, Modulus == m}, x]



MuPAD
n mod m
solve(poly(e, [x], IntMod(m))=0, x)



Octave
 
 



Pari
 
 



Reduce
on modular;
load_ package(modsr)$   on modular;



 
setmod m$   n
setmod m$   m_solve(e = 0, x)



Scilab
 
 



Sumit
 
 



Yacas
 
 






 
Put over common denominator
Expand into separate fractions



FriCAS
a/b + c/d
(ad + bc)/(b*d) :: _



 
 
  MPOLY([a], FRAC POLY INT)



Derive
FACTOR(a/b + c/d, Trivial)
EXPAND((ad + bc)/(b*d))



DoCon
 
 



GAP
a/b+c/d
 



Gmp
 
 



Macsyma
xthru(a/b + c/d)
expand((ad + bc)/(b*d))



Magnus
 
 



Maxima
xthru(a/b + c/d)
expand((ad + bc)/(b*d))



Maple
normal(a/b + c/d)
expand((ad + bc)/(b*d))



Mathematica
Together[a/b + c/d]
Apart[(ad + bc)/(b*d)]



MuPAD
normal(a/b + c/d)
expand((ad + bc)/(b*d))



Octave
 
 



Pari
 
 



Reduce
a/b + c/d
on div; (ad + bc)/(b*d)



Scilab
 
 



Sumit
 
 



Yacas
 
 






 
Manipulate the root of a polynomial



FriCAS
a:= rootOf(x^2 - 2);   a^2



Derive
 



DoCon
 



GAP
x:=X(Rationals,"x");



 
  a:=RootOfDefiningPolynomial(AlgebraicExtension(Rationals,x^2-2));
a^2



Gmp
 



Macsyma
algebraic:true$   tellrat(a^2 - 2)$   rat(a^2);



Magnus
 



Maxima
algebraic:true$   tellrat(a^2 - 2)$   rat(a^2);



Maple
a:= RootOf(x^2 - 2):   simplify(a^2);



Mathematica
a = Root[#^2 - 2 &, 2]   a^2



MuPAD
F := Dom::AlgebraicExtension(Dom::Rational, a^2-2):



 
F(a)^2



Octave
 



Pari
 



Reduce
load_ package(arnum)$   defpoly(a^2 - 2);   a^2;



Scilab
 



Sumit
 



Yacas
 






 
Noncommutative multiplication
Solve a pair of equations



FriCAS
In noncommutaive domains usual * is noncommutative
solve([eqn1, eqn2], [x, y])



Derive
x :epsilon Nonscalar
SOLVE([eqn1, eqn2], [x, y])



 
y :epsilon Nonscalar
 



 
x . y
 



DoCon
 
 



GAP
*
 



Gmp
 
 



Macsyma
x . y
solve([eqn1, eqn2], [x, y])



Magnus
 
 



Maxima
x . y
solve([eqn1, eqn2], [x, y])



Maple
x &* y
solve({eqn1, eqn2}, {x, y})



Mathematica
x ** y
Solve[{eqn1, eqn2}, {x, y}]



MuPAD
 
solve({eqn1, eqn2}, {x, y})



Octave
 
 



Pari
 
 



Reduce
operator x, y;
solve({eqn1, eqn2}, {x, y})



 
noncom x, y;
 



 
x() * y()
 



Scilab
 
 



Sumit
 
 



Yacas
 
 






 
Decrease/increase angles in trigonometric functions



FriCAS
simplify(normalize(sin(2*x)))



Derive
Trigonometry:= Expand
Trigonometry:= Collect



 
sin(2*x)
2sin(x)cos(x)



DoCon
 
 



GAP
 
 



Gmp
 
 



Macsyma
trigexpand(sin(2*x))
trigreduce(2sin(x)cos(x))



Magnus
 
 



Maxima
trigexpand(sin(2*x))
trigreduce(2sin(x)cos(x))



Maple
expand(sin(2*x))
combine(2sin(x)cos(x))



Mathematica
TrigExpand[Sin[2*x]]
TrigReduce[2*Sin[x]*Cos[x]]



MuPAD
expand(sin(2*x))
combine(2sin(x)cos(x), sincos)
        



Octave
 
 



Pari
 
 



Reduce
load_ package(assist)$



 
trigexpand(sin(2*x))
trigreduce(2sin(x)cos(x))



Scilab
 
 



Sumit
 
 



Yacas
 
 






 
Gröbner basis



FriCAS
groebner([p1, p2, ...])



Derive
 



DoCon
 



GAP
 



Gmp
 



Macsyma
grobner([p1, p2, ...])



Magnus
 



Maxima
grobner([p1, p2, ...])



Maple
Groebner[gbasis]([p1, p2, ...], plex(x1, x2, ...))



Mathematica
GroebnerBasis[{p1, p2, ...}, {x1, x2, ...}]



MuPAD
groebner::gbasis([p1, p2, ...])



Octave
 



Pari
 



Reduce
load_ package(groebner)$   groebner({p1, p2, ...})



Scilab
 



Sumit
 



Yacas
 






 
Factorization of e over i = -1



FriCAS
factor(e, [rootOf(i^2 + 1)])



Derive
FACTOR(e, Complex)



DoCon
 



GAP
Factors(GaussianIntegers,e)



Gmp
 



Macsyma
gfactor(e); or  factor(e, i^2 + 1);



Magnus
 



Maxima
gfactor(e); or  factor(e, i^2 + 1);



Maple
factor(e, I);



Mathematica
Factor[e, Extension -> I]



MuPAD
QI:= Dom::AlgebraicExtension(Dom::Rational, i^2 + 1);



 
QI::name:= "QI":   Factor(poly(e, QI));



Octave
 



Pari
 



Reduce
on complex, factor;   e;   off complex, factor;



Scilab
 



Sumit
 



Yacas
 






 
Real part
Convert a complex expr. to rectangular form



FriCAS
real(f(z))
complexForm(f(z))



Derive
RE(f(z))
f(z)



DoCon
 
 



GAP
(f(z)+GaloisCyc(f(z),-1))/2
 



Gmp
 
 



Macsyma
realpart(f(z))
rectform(f(z))



Magnus
 
 



Maxima
realpart(f(z))
rectform(f(z))



Maple
Re(f(z))
evalc(f(z))



Mathematica
Re[f![z]]
ComplexExpand[f[z]]



MuPAD
Re(f(z))
rectform(f(z))



Octave
 
 



Pari
 
 



Reduce
repart(f(z))
repart(f(z)) + i*impart(f(z))



Scilab
 
 



Sumit
 
 



Yacas
 
 






 
Matrix addition
Matrix multiplication
Matrix transpose



FriCAS
A + B
A * B
transpose(A)



Derive
A + B
A . B
A`



DoCon
 
 
 



GAP
A + B
A * B
TransposedMat(A)



Gmp
 
 
 



Macsyma
A + B
A . B
transpose(A)



Magnus
 
 
 



Maxima
A + B
A . B
transpose(A)



Maple
evalm(A + B)
evalm(A &* B)
linalg[transpose](A)



Mathematica
A + B
A . B
Transpose[A]



MuPAD
A + B
A * B
linalg::transpose(A)



Octave
 
 
 



Pari
 
 
 



Reduce
A + B
A * B
tp(A)



Scilab
 
 
 



Sumit
 
 
 



Yacas
 
 
 






 
Solve the matrix equation A x = b



FriCAS
solve(A, transpose(b)) . 1 . particular :: Matrix ___



Derive
 



DoCon
 



GAP
SolutionMat(TransposedMat(A),b)



Gmp
 



Macsyma
xx: genvector('x, mat_nrows(b))$



 
x: part(matlinsolve(A . xx = b, xx), 1, 2)



Magnus
 



Maxima
xx: genvector('x, mat_nrows(b))$



 
x: part(matlinsolve(A . xx = b, xx), 1, 2)



Maple
x:= linalg[linsolve](A, b)



Mathematica
x = LinearSolve[A, b]



MuPAD
matlinsolve(A, b)



Octave
 



Pari
 



Reduce
 



Scilab
 



Sumit
 



Yacas
 






 
Sum: åi = 1n f(i)
Product: Õi = 1n f(i)



FriCAS
sum(f(i), i = 1..n)
product(f(i), i = 1..n)



Derive
SUM(f(i), i, 1, n)
PRODUCT(f(i), i, 1, n)



DoCon
 
 



GAP
Sum([1..n],f)
Product([1..n],f)



Gmp
 
 



Macsyma
closedform(
closedform(



 
  sum(f(i), i, 1, n))
  product(f(i), i, 1, n))



Magnus
 
 



Maxima
closedform(
closedform(



 
  sum(f(i), i, 1, n))
  product(f(i), i, 1, n))



Maple
sum(f(i), i = 1..n)
product(f(i), i = 1..n)



Mathematica
Sum[f![i], {i, 1, n}]
Product[f[i], {i, 1, n}]



MuPAD
sum(f(i), i = 1..n)
product(f(i), i = 1..n)



Octave
 
 



Pari
 
 



Reduce
sum(f(i), i, 1, n)
prod(f(i), i, 1, n)



Scilab
 
 



Sumit
 
 



Yacas
 
 






 
Limit: limx ® 0- f(x)
Taylor/Laurent/etc. series



FriCAS
limit(f(x), x = 0, "left")
series(f(x), x = 0, 3)



Derive
LIM(f(x), x, 0, -1)
TAYLOR(f(x), x, 0, 3)



DoCon
 
 



GAP
 
 



Gmp
 
 



Macsyma
limit(f(x), x, 0, minus)
taylor(f(x), x, 0, 3)



Magnus
 
 



Maxima
limit(f(x), x, 0, minus)
taylor(f(x), x, 0, 3)



Maple
limit(f(x), x = 0, left)
series(f(x), x = 0, 4)



Mathematica
Limit[f![x], x->0, Direction->1]
Series[f![x],{x, 0, 3}]



MuPAD
limit(f(x), x = 0, Left)
series(f(x), x = 0, 4)



Octave
 
 



Pari
 
 



Reduce
limit!-(f(x), x, 0)
taylor(f(x), x, 0, 3)



Scilab
 
 



Sumit
 
 



Yacas
 
 






 
Differentiate: d3 f(x, y)/dx   dy2
      Integrate: ò01 f(x)   dx



FriCAS
D(f(x, y), [x, y], [1, 2])
integrate(f(x), x = 0..1)



Derive
DIF(DIF(f(x, y), x), y, 2)
INT(f(x), x, 0, 1)



DoCon
 
 



GAP
 
 



Gmp
 
 



Macsyma
diff(f(x, y), x, 1, y, 2)
integrate(f(x), x, 0, 1)



Magnus
 
 



Maxima
diff(f(x, y), x, 1, y, 2)
integrate(f(x), x, 0, 1)



Maple
diff(f(x, y), x, y$2)
int(f(x), x = 0..1)



Mathematica
D[f![x, y], x, {y, 2}]
Integrate[f[x], {x, 0, 1}]



MuPAD
diff(f(x, y), x, y$2)
int(f(x), x = 0..1)



Octave
 
 



Pari
 
 



Reduce
df(f(x, y), x, y, 2)
int(f(x), x, 0, 1)



Scilab
 
 



Sumit
 
 



Yacas
 
 






 
Laplace transform
Inverse Laplace transform



FriCAS
laplace(e, t, s)
inverseLaplace(e, s, t)



Derive
LAPLACE(e, t, s)
 



DoCon
 
 



GAP
 
 



Gmp
 
 



Macsyma
laplace(e, t, s)
ilt(e, s, t)



Magnus
 
 



Maxima
laplace(e, t, s)
ilt(e, s, t)



Maple
inttrans[laplace](e,t,s)
inttrans[invlaplace](e,s,t)



Mathematica
  << Calculus`LaplaceTransform`



 
LaplaceTransform[e, t, s]
InverseLaplaceTransform[e,s,t]
        



MuPAD
transform::laplace(e,t,s)
transform::invlaplace(e, s, t)



Octave
 
 



Pari
 
 



Reduce
  load package(laplace)$   load package(defint)$
        



 
laplace(e, t, s)
invlap(e, t, s)



Scilab
 
 



Sumit
 
 



Yacas
 
 






 
Solve an ODE (with the initial condition y'(0) = 1)



FriCAS
solve(eqn, y, x)



Derive
APPLY IC(RHS(ODE(eqn, x, y, y)), [x, 0], [y, 1])



DoCon
 



GAP
 



Gmp
 



Macsyma
ode_ibc(ode(eqn, y(x), x), x = 0, diff(y(x), x) = 1)



Magnus
 



Maxima
ode_ibc(ode(eqn, y(x), x), x = 0, diff(y(x), x) = 1)



Maple
dsolve({eqn, D(y)(0) = 1}, y(x))



Mathematica
DSolve[{eqn, y'[0] == 1}, y[x], x]



MuPAD
solve(ode({eqn, y'(0) = 1}, y(x)))



Octave
 



Pari
 



Reduce
odesolve(eqn, y(x), x)



Scilab
 



Sumit
 



Yacas
 






 
Define the differential operator L = Dx + I and apply it to sinx



FriCAS
DD : LODO(Expression Integer, e +-> D(e, x)) := D();



 
L:= DD + 1;   L(sin(x))



Derive
 



DoCon
 



GAP
 



Gmp
 



Macsyma
load(opalg)$   L: (diffop(x) - 1)$   L(sin(x));



Magnus
 



Maxima
load(opalg)$   L: (diffop(x) - 1)$   L(sin(x));



Maple
id:= x -> x:   L:= (D + id):   L(sin)(x);



Mathematica
L = D[#, x]& + Identity;   Through[L[Sin[x]]]



MuPAD
L:= (D + id):   L(sin)(x);



Octave
 



Pari
 



Reduce
 



Scilab
 



Sumit
 



Yacas
 






 
2D plot of two separate curves overlayed



FriCAS
draw(x, x = 0..1);   draw(acsch(x), x = 0..1);



Derive
[Plot Overlay]



DoCon
 



GAP
 



Gmp
 



Macsyma
plot(x, x, 0, 1)$   plot(acsch(x), x, 0, 1)$



Magnus
 



Maxima
plot(x, x, 0, 1)$   plot(acsch(x), x, 0, 1)$



Maple
plot({x, arccsch(x)}, x = 0..1):



Mathematica
Plot[{x, ArcCsch[x]}, {x, 0, 1}];



MuPAD
plotfunc2d(x, arcsech(x), x = 0..1):



Octave
 



Pari
 



Reduce
load_ package(gnuplot)$   plot(y = x, x = (0 .. 1))$



 
plot(y = acsch(x), x = (0 .. 1))$



Scilab
 



Sumit
 



Yacas
 






 
Simple 3D plotting



FriCAS
draw(abs(x*y), x = 0..1, y = 0..1);



Derive
[Plot Overlay]



DoCon
 



GAP
 



Gmp
 



Macsyma
plot3d(abs(x*y), x, 0, 1, y, 0, 1)$



Magnus
 



Maxima
plot3d(abs(x*y), x, 0, 1, y, 0, 1)$



Maple
plot3d(abs(x*y), x = 0..1, y = 0..1):



Mathematica
Plot3D[Abs![x*y], {x, 0, 1}, {y, 0, 1}];



MuPAD
plotfunc3d(abs(x*y), x = 0..1, y = 0..1):



Octave
 



Pari
 



Reduce
load_ package(gnuplot)$



 
plot(z = abs(x*y), x = (0 .. 1), y = (0 .. 1))$



Scilab
 



Sumit
 



Yacas
 










1
Only if the pattern is not a keyword and then the matches are
simplistic.

6
Variables can be assigned to generators of a suitable free
object, for example x:=X(Rationals,"x"); or f:=FreeGroup(2);x:=f.1;.

6
procedure xapply(f, lst); lisp(f . cdr(lst))$

6
TERMS, FACTORS, NUMERATOR, LHS, etc.

7
The following commands work only on expressions that consist of a
single level (e.g., x + y + z but not a/b + c/d).

7
Some editing of file will be necessary for all systems but
Maple and Mathematica.

8
ER represents special cyclotomic numbers and is not a
root function.

8
This is an option for Integrate.









This document was translated from LATEX by
HEVEA.







Remarks concerning GAP --Christian Sievers,  Tue, 23 May 2006 11:39:26 -0500 reply
While the given GAP command does generate the list [1, 2, ..., n], the other examples seem to generate the list
[f(1), f(2), ..., f(n)].  This can be done with:

  List([1..n],f);





I'm not sure what Apply a fun. to a list of its args is supposed to mean, but my answer to that request is:

  CallFuncList(f,l);





A groebner basis can be computed with:

  GroebnerBasis([p1,p2,...],MonomialLexOrdering());





macsyma dead??? --unknown,  Sat, 17 Jun 2006 12:42:22 -0500 reply
Hi
I think it is still alive somehow,
see for example:
http://maxima.sourceforge.net


Bye


Other systems? --znmeb,  Sat, 17 Jun 2006 19:38:19 -0500 reply
Have we ruled out "special purpose" CAS packages, such as Ginac and Singular?


Re: Have we ruled out "special purpose" CAS packages? --Bill Page,  Mon, 19 Jun 2006 11:02:02 -0500 reply
Not at all. Please feel free to add missing information.


Dirac delta and piecewise --konstantin,  Sun, 17 Sep 2006 13:33:02 -0500 reply
Dirak delta and piecewise was implemented as built-in in Mathematica: use DiracDelta?[x]? and Piecewise[{{-x,x<0},{x,x>0}}]?


Pamphlet/LaTeX version of this page --Cliff Yapp,  Sun, 17 Sep 2006 22:06:37 -0500 reply
(Note that the pamphlet form of this document can be found here: Rosetta
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                nbsp;plot(acsch(x), x, 0, 1)$$\newpage
[14]
 Misplaced alignment tab character &.
l.136 $$ &
          nbsp;&nbsp;plot(y = x, x = (0 .. 1))$$
 Misplaced alignment tab character &.
l.136 $$ &nbsp;&
                nbsp;plot(y = x, x = (0 .. 1))$$
[15] (./7935641049083376220-16.0px.aux) )
(see the transcript file for additional information)
Output written on 7935641049083376220-16.0px.dvi (15 pages, 4564 bytes).
Transcript written on 7935641049083376220-16.0px.log.




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