(directly go to documentation on : FullForm, Echo, PrettyForm, EvalFormula, TeXForm, CForm, IsCFormable, Write, WriteString, Space, NewLine, FromFile, FromString, ToFile, ToString, Read, ToStdout, ReadCmdLineString, LispRead, LispReadListed, ReadToken, Load, Use, DefLoad, FindFile, PatchLoad, Nl, V, InVerboseMode, Plot2D, Plot3DS, XmlExplodeTag, DefaultTokenizer, XmlTokenizer, OMForm, OMRead, OMDef. )

28. Input/output and plotting

This chapter contains commands to use for input and output and plotting. All output commands write to the same destination stream, called the "current output". This is initially the screen, but may be redirected by some commands. Similarly, most input commands read from the "current input" stream, which can also be redirected. The exception to this rule are the commands for reading script files, which simply read a specified file.

FullForm print an expression in LISP-format
Echo high-level printing routine
PrettyForm print an expression nicely with ASCII art
EvalFormula print an evaluation nicely with ASCII art
TeXForm export expressions to LaTeX
CForm export expression to C++ code
IsCFormable check possibility to export expression to C++ code
Write low-level printing routine
WriteString low-level printing routine for strings
Space print one or more spaces
NewLine print one or more newline characters
FromFile connect current input to a file
FromString connect current input to a string
ToFile connect current output to a file
ToString connect current output to a string
Read read an expression from current input
ToStdout select initial output stream for output
ReadCmdLineString read an expression from command line and return in string
LispRead read expressions in LISP syntax
LispReadListed read expressions in LISP syntax
ReadToken read a token from current input
Load evaluate all expressions in a file
Use load a file, but not twice
DefLoad load a .def file
FindFile find a file in the current path
PatchLoad execute commands between <? and ?> in file
Nl the newline character
V, InVerboseMode set verbose output mode
Plot2D adaptive two-dimensional plotting
Plot3DS three-dimensional (surface) plotting
XmlExplodeTag convert XML strings to tag objects
DefaultTokenizer select the default syntax tokenizer for parsing the input
XmlTokenizer select an XML syntax tokenizer for parsing the input
OMForm convert Yacas expression to OpenMath
OMRead convert expression from OpenMath to Yacas expression
OMDef define translations from Yacas to OpenMath and vice-versa.


FullForm -- print an expression in LISP-format

Internal function
Calling format:
FullForm(expr)

Parameters:
expr -- expression to be printed in LISP-format

Description:
Evaluates "expr", and prints it in LISP-format on the current output. It is followed by a newline. The evaluated expression is also returned.

This can be useful if you want to study the internal representation of a certain expression.

Examples:
In> FullForm(a+b+c);
(+ (+ a b )c )
Out> a+b+c;
In> FullForm(2*I*b^2);
(* (Complex 0 2 )(^ b 2 ))
Out> Complex(0,2)*b^2;

The first example shows how the expression a+b+c is internally represented. In the second example, 2*I is first evaluated to Complex(0,2) before the expression is printed.

See also:
LispRead , Listify , Unlist .


Echo -- high-level printing routine

Standard library
Calling format:
Echo(item)
Echo(list)
Echo(item,item,item,...)

Parameters:
item -- the item to be printed

list -- a list of items to be printed

Description:
If passed a single item, Echo will evaluate it and print it to the current output, followed by a newline. If item is a string, it is printed without quotation marks.

If there is one argument, and it is a list, Echo will print all the entries in the list subsequently to the current output, followed by a newline. Any strings in the list are printed without quotation marks. All other entries are followed by a space.

Echo can be called with a variable number of arguments, they will all be printed, followed by a newline.

Echo always returns True.

Examples:
In> Echo(5+3);
 8
Out> True;
In> Echo({"The square of two is ", 2*2});
The square of two is 4
Out> True;
In> Echo("The square of two is ", 2*2);
The square of two is 4 
Out> True;

Note that one must use the second calling format if one wishes to print a list:

In> Echo({a,b,c});
a b c
Out> True;
In> Echo({{a,b,c}});
{a,b,c}
Out> True;

See also:
PrettyForm , Write , WriteString , RuleBaseListed .


PrettyForm -- print an expression nicely with ASCII art

Standard library
Calling format:
PrettyForm(expr)

Parameters:
expr -- an expression

Description:
PrettyForm renders an expression in a nicer way, using ascii art. This is generally useful when the result of a calculation is more complex than a simple number.

Examples:
In> Taylor(x,0,9)Sin(x)
Out> x-x^3/6+x^5/120-x^7/5040+x^9/362880;
In> PrettyForm(%)

     3    5      7       9
    x    x      x       x
x - -- + --- - ---- + ------
    6    120   5040   362880

Out> True;

See also:
EvalFormula , PrettyPrinter'Set .


EvalFormula -- print an evaluation nicely with ASCII art

Standard library
Calling format:
EvalFormula(expr)

Parameters:
expr -- an expression

Description:
Show an evaluation in a nice way, using PrettyPrinter'Set to show 'input = output'.

Examples:
In> EvalFormula(Taylor(x,0,7)Sin(x))

                                      3    5
                                     x    x  
Taylor( x , 0 , 5 , Sin( x ) ) = x - -- + ---
                                     6    120

See also:
PrettyForm .


TeXForm -- export expressions to LaTeX

Standard library
Calling format:
TeXForm(expr)

Parameters:
expr -- an expression to be exported

Description:
TeXForm returns a string containing a LaTeX representation of the Yacas expression expr. Currently the exporter handles most expression types but not all.

Example:
In> TeXForm(Sin(a1)+2*Cos(b1))
Out> "$\sin a_{1} + 2 \cos b_{1}$";

See also:
PrettyForm , CForm .


CForm -- export expression to C++ code

Standard library
Calling format:
CForm(expr)

Parameters:
expr -- expression to be exported

Description:
CForm returns a string containing C++ code that attempts to implement the Yacas expression expr. Currently the exporter handles most expression types but not all.

Example:
In> CForm(Sin(a1)+2*Cos(b1));
Out> "sin(a1) + 2 * cos(b1)";

See also:
PrettyForm , TeXForm , IsCFormable .


IsCFormable -- check possibility to export expression to C++ code

Standard library
Calling format:
IsCFormable(expr)
IsCFormable(expr, funclist)

Parameters:
expr -- expression to be exported (this argument is not evaluated)

funclist -- list of "allowed" function atoms

Description:
IsCFormable returns True if the Yacas expression expr can be exported into C++ code. This is a check whether the C++ exporter CForm can be safely used on the expression.

A Yacas expression is considered exportable if it contains only functions that can be translated into C++ (e.g. UnList cannot be exported). All variables and constants are considered exportable.

The verbose option prints names of functions that are not exportable.

The second calling format of IsCFormable can be used to "allow" certain function names that will be available in the C++ code.

Examples:
In> IsCFormable(Sin(a1)+2*Cos(b1))
Out> True;
In> V(IsCFormable(1+func123(b1)))
IsCFormable: Info: unexportable function(s):
  func123
Out> False;
This returned False because the function func123 is not available in C++. We can explicitly allow this function and then the expression will be considered exportable:

In> IsCFormable(1+func123(b1), {func123})
Out> True;

See also:
CForm , V .


Write -- low-level printing routine

Internal function
Calling format:
Write(expr, ...)

Parameters:
expr -- expression to be printed

Description:
The expression "expr" is evaluated and written to the current output. Note that Write accept an arbitrary number of arguments, all of which are written to the current output (see second example). Write always returns True.

Examples:
In> Write(1);
1Out> True;
In> Write(1,2);
 1 2Out> True;

Write does not write a newline, so the Out> prompt immediately follows the output of Write.

See also:
Echo , WriteString .


WriteString -- low-level printing routine for strings

Internal function
Calling format:
WriteString(string)

Parameters:
string -- the string to be printed

Description:
The expression "string" is evaluated and written to the current output without quotation marks. The argument should be a string. WriteString always returns True.

Examples:
In> Write("Hello, world!");
"Hello, world!"Out> True;
In> WriteString("Hello, world!");
Hello, world!Out> True;

This example clearly shows the difference between Write and WriteString. Note that Write and WriteString do not write a newline, so the Out> prompt immediately follows the output.

See also:
Echo , Write .


Space -- print one or more spaces

Standard library
Calling format:
Space()
Space(nr)

Parameters:
nr -- the number of spaces to print

Description:
The command Space() prints one space on the current output. The second form prints nr spaces on the current output. The result is always True.

Examples:
In> Space(5);
     Out> True;

See also:
Echo , Write , NewLine .


NewLine -- print one or more newline characters

Standard library
Calling format:
NewLine()
NewLine(nr)

Parameters:
nr -- the number of newline characters to print

Description:
The command NewLine() prints one newline character on the current output. The second form prints "nr" newlines on the current output. The result is always True.

Examples:
In> NewLine();

Out> True;

See also:
Echo , Write , Space .


FromFile -- connect current input to a file

Internal function
Calling format:
FromFile(name) body

Parameters:
name - string, the name of the file to read

body - expression to be evaluated

Description:
The current input is connected to the file "name". Then the expression "body" is evaluated. If some functions in "body" try to read from current input, they will now read from the file "name". Finally, the file is closed and the result of evaluating "body" is returned.

Examples:
Suppose that the file foo contains

2 + 5;

Then we can have the following dialogue:

In> FromFile("foo") res := Read();
Out> 2+5;
In> FromFile("foo") res := ReadToken();
Out> 2;

See also:
ToFile , FromString , Read , ReadToken .


FromString -- connect current input to a string

Internal function
Calling format:
FromString(str) body;

Parameters:
str -- a string containing the text to parse

body -- expression to be evaluated

Description:
The commands in "body" are executed, but everything that is read from the current input is now read from the string "str". The result of "body" is returned.

Examples:
In> FromString("2+5; this is never read") \
  res := Read();
Out> 2+5;
In> FromString("2+5; this is never read") \
  res := Eval(Read());
Out> 7;

See also:
ToString , FromFile , Read , ReadToken .


ToFile -- connect current output to a file

Internal function
Calling format:
ToFile(name) body

Parameters:
name -- string, the name of the file to write the result to

body -- expression to be evaluated

Description:
The current output is connected to the file "name". Then the expression "body" is evaluated. Everything that the commands in "body" print to the current output, ends up in the file "name". Finally, the file is closed and the result of evaluating "body" is returned.

If the file is opened again, the old contents will be overwritten. This is a limitation of ToFile: one cannot append to a file that has already been created.

Examples:
Here is how one can create a file with C code to evaluate an expression:

In> ToFile("expr1.c") WriteString(
  CForm(Sqrt(x-y)*Sin(x)) );
Out> True;
The file expr1.c was created in the current working directory and it contains the line
sqrt(x-y)*sin(x)

As another example, take a look at the following command:

In> [ Echo("Result:");  \
  PrettyForm(Taylor(x,0,9) Sin(x)); ];
Result:

     3    5      7       9
    x    x      x       x
x - -- + --- - ---- + ------
    6    120   5040   362880

Out> True;

Now suppose one wants to send the output of this command to a file. This can be achieved as follows:

In> ToFile("out") [ Echo("Result:");  \
  PrettyForm(Taylor(x,0,9) Sin(x)); ];
Out> True;

After this command the file out contains:

Result:

     3    5      7       9
    x    x      x       x
x - -- + --- - ---- + ------
    6    120   5040   362880

See also:
FromFile , ToString , Echo , Write , WriteString , PrettyForm , Taylor .


ToString -- connect current output to a string

Internal function
Calling format:
ToString() body

Parameters:
body -- expression to be evaluated

Description:
The commands in "body" are executed. Everything that is printed on the current output, by Echo for instance, is collected in a string and this string is returned.

Examples:
In> str := ToString() [ WriteString(  \
  "The square of 8 is "); Write(8^2); ];
Out> "The square of 8 is  64";

See also:
FromFile , ToString , Echo , Write , WriteString .


Read -- read an expression from current input

Internal function
Calling format:
Read()

Description:
Read an expression from the current input, and return it unevaluated. When the end of an input file is encountered, the token atom EndOfFile is returned.

Examples:
In> FromString("2+5;") Read();
Out> 2+5;
In> FromString("") Read();
Out> EndOfFile;

See also:
FromFile , FromString , LispRead , ReadToken , Write .


ToStdout -- select initial output stream for output

Internal function
Calling format:
ToStdout() body

Parameters:
body -- expression to be evaluated

Description:
When using ToString or ToFile, it might happen that something needs to be written to the standard default initial output (typically the screen). ToStdout can be used to select this stream.

Example:
In> ToString()[Echo("aaaa");ToStdout()Echo("bbbb");];
bbbb
Out> "aaaa
"

See also:
ToString , ToFile .


ReadCmdLineString -- read an expression from command line and return in string

Internal function
Calling format:
ReadCmdLineString(prompt)

Parameters:
prompt -- string representing the prompt shown on screen

Description:
This function allows for interactive input similar to the command line. When using this function, the history from the command line is also available.

The result is returned in a string, so it still needs to be parsed.

This function will typically be used in situations where one wants a custom read-eval-print loop.

Examples:
The following defines a function that when invoked keeps asking for an expression (the read step), and then takes the derivative of it (the eval step) and then uses PrettyForm to display the result (the print step).

In> ReEvPr() := \
In>   While(True) [ \
In>     PrettyForm(Deriv(x) \
In>      FromString(ReadCmdLineString("Deriv> "):";")Read()); \
In> ];
Out> True;

Then one can invoke the command, from which the following interaction might follow:

In> ReEvPr()
Deriv> Sin(a^2*x/b)

   /  2     \         
   | a  * x |    2    
Cos| ------ | * a  * b
   \   b    /         
----------------------
           2          
          b           

Deriv> Sin(x)

Cos( x )

Deriv> 

See also:
Read , LispRead , LispReadListed .


LispRead -- read expressions in LISP syntax


LispReadListed -- read expressions in LISP syntax

Internal function
Calling format:
LispRead()
LispReadListed()

Description:
The function LispRead reads an expression in the LISP syntax from the current input, and returns it unevaluated. When the end of an input file is encountered, the special token atom EndOfFile is returned.

The Yacas expression a+b is written in the LISP syntax as (+ a b). The advantage of this syntax is that it is less ambiguous than the infix operator grammar that Yacas uses by default.

The function LispReadListed reads a LISP expression and returns it in a list, instead of the form usual to Yacas (expressions). The result can be thought of as applying Listify to LispRead. The function LispReadListed is more useful for reading arbitrary LISP expressions, because the first object in a list can be itself a list (this is never the case for Yacas expressions where the first object in a list is always a function atom).

Examples:
In> FromString("(+ a b)") LispRead();
Out> a+b;
In> FromString("(List (Sin x) (- (Cos x)))") \
  LispRead();
Out> {Sin(x),-Cos(x)};
In> FromString("(+ a b)")LispRead()
Out> a+b;
In> FromString("(+ a b)")LispReadListed()
Out> {+,a,b};

See also:
FromFile , FromString , Read , ReadToken , FullForm .


ReadToken -- read a token from current input

Internal function
Calling format:
ReadToken()

Description:
Read a token from the current input, and return it unevaluated. The returned object is a Yacas atom (not a string). When the end of an input file is encountered, the token atom EndOfFile is returned.

A token is for computer languages what a word is for human languages: it is the smallest unit in which a command can be divided, so that the semantics (that is the meaning) of the command is in some sense a combination of the semantics of the tokens. Hence a := foo consists of three tokens, namely a, :=, and foo.

The parsing of the string depends on the syntax of the language. The part of the kernel that does the parsing is the "tokenizer". Yacas can parse its own syntax (the default tokenizer) or it can be instructed to parse XML or C++ syntax using the directives DefaultTokenizer or XmlTokenizer. Setting a tokenizer is a global action that affects all ReadToken calls.

Examples:
In> FromString("a := Sin(x)") While \
  ((tok := ReadToken()) != EndOfFile) \
  Echo(tok);
a
:=
Sin
(
x
)
Out> True;

We can read some junk too:
In> FromString("-$3")ReadToken();
Out> -$;
The result is an atom with the string representation -$. Yacas assumes that -$ is an operator symbol yet to be defined. The "3" will be in the next token. (The results will be different if a non-default tokenizer is selected.)

See also:
FromFile , FromString , Read , LispRead , DefaultTokenizer .


Load -- evaluate all expressions in a file

Internal function
Calling format:
Load(name)

Parameters:
name -- string, name of the file to load

Description:
The file "name" is opened. All expressions in the file are read and evaluated. Load always returns true.

See also:
Use , DefLoad , DefaultDirectory , FindFile .


Use -- load a file, but not twice

Internal function
Calling format:
Use(name)

Parameters:
name -- string, name of the file to load

Description:
If the file "name" has been loaded before, either by an earlier call to Use or via the DefLoad mechanism, nothing happens. Otherwise all expressions in the file are read and evaluated. Use always returns true.

The purpose of this function is to make sure that the file will at least have been loaded, but is not loaded twice.

See also:
Load , DefLoad , DefaultDirectory .


DefLoad -- load a .def file

Internal function
Calling format:
DefLoad(name)

Parameters:
name -- string, name of the file (without .def suffix)

Description:
The suffix .def is appended to "name" and the file with this name is loaded. It should contain a list of functions, terminated by a closing brace \} (the end-of-list delimiter). This tells the system to load the file "name" as soon as the user calls one of the functions named in the file (if not done so already). This allows for faster startup times, since not all of the rules databases need to be loaded, just the descriptions on which files to load for which functions.

See also:
Load , Use , DefaultDirectory .


FindFile -- find a file in the current path

Internal function
Calling format:
FindFile(name)

Parameters:
name -- string, name of the file or directory to find

Description:
The result of this command is the full path to the file that would be opened when the command Load(name) would be invoked. This means that the input directories are subsequently searched for a file called "name". If such a file is not found, FindFile returns an empty string.

FindFile("") returns the name of the default directory (the first one on the search path).

See also:
Load , DefaultDirectory .


PatchLoad -- execute commands between <? and ?> in file

Internal function
Calling format:
PatchLoad(name)

Parameters:
name -- string, name of the file to "patch"

Description:
PatchLoad loads in a file and outputs the contents to the current output. The file can contain blocks delimited by <? and ?> (meaning "Yacas Begin" and "Yacas End"). The piece of text between such delimiters is treated as a separate file with Yacas instructions, which is then loaded and executed. All output of write statements in that block will be written to the same current output.

This is similar to the way PHP works. You can have a static text file with dynamic content generated by Yacas.

See also:
PatchString , Load .


Nl -- the newline character

Standard library
Calling format:
Nl()

Description:
This function returns a string with one element in it, namely a newline character. This may be useful for building strings to send to some output in the end.

Note that the second letter in the name of this command is a lower case L (from "line").

Examples:
In> WriteString("First line" : Nl() : "Second line" : Nl());
First line
Second line
Out> True;

See also:
NewLine .


V, InVerboseMode -- set verbose output mode

Standard library
Calling format:
V(expression)
InVerboseMode()

Parameters:
expression -- expression to be evaluated in verbose mode

Description:
The function V(expression) will evaluate the expression in verbose mode. Various parts of Yacas can show extra information about the work done while doing a calculation when using V.

In verbose mode, InVerboseMode() will return True, otherwise it will return False.

Examples:
In> OldSolve({x+2==0},{x})
Out> {{-2}};
In> V(OldSolve({x+2==0},{x}))
Entering OldSolve
From  x+2==0  it follows that  x  = -2 
   x+2==0  simplifies to  True 
Leaving OldSolve
Out> {{-2}};
In> InVerboseMode()
Out> False
In> V(InVerboseMode())
Out> True

See also:
Echo , N , OldSolve .


Plot2D -- adaptive two-dimensional plotting

Standard library
Calling format:
Plot2D(f(x))
Plot2D(f(x), a:b)
Plot2D(f(x), a:b, option=value)
Plot2D(f(x), a:b, option=value, ...)
Plot2D(list, ...)

Parameters:
f(x) -- unevaluated expression containing one variables (function to be plotted)

list -- list of functions to plot

a, b -- numbers, plotting range in the x coordinate

option -- atom, option name

value -- atom, number or string (value of option)

Description:
The routine Plot2D performs adaptive plotting of one or several functions of one variable in the specified range. The result is presented as a line given by the equation y=f(x). Several functions can be plotted at once. Various plotting options can be specified. Output can be directed to a plotting program (the default is to use data) to a list of values.

The function parameter f(x) must evaluate to a Yacas expression containing at most one variable. (The variable does not have to be called x.) Also, N(f(x)) must evaluate to a real (not complex) numerical value when given a numerical value of the argument x. If the function f(x) does not satisfy these requirements, an error is raised.

Several functions may be specified as a list and they do not have to depend on the same variable, for example, {f(x), g(y)}. The functions will be plotted on the same graph using the same coordinate ranges.

If you have defined a function which accepts a number but does not accept an undefined variable, Plot2D will fail to plot it. Use NFunction to overcome this difficulty.

Data files are created in a temporary directory /tmp/plot.tmp/ unless otherwise requested. File names and other information is printed if InVerboseMode() returns True on using V().

The current algorithm uses Newton-Cotes quadratures and some heuristics for error estimation (see The Yacas book of algorithms, Chapter 3, Section 1 ). The initial grid of points+1 points is refined between any grid points a, b if the integral Integrate(x,a,b)f(x) is not approximated to the given precision by the existing grid.

Default plotting range is -5:5. Range can also be specified as x= -5:5 (note the mandatory space separating "=" and "-"); currently the variable name x is ignored in this case.

Options are of the form option=value. Currently supported option names are: "points", "precision", "depth", "output", "filename", "yrange". Option values are either numbers or special unevaluated atoms such as data. If you need to use the names of these atoms in your script, strings can be used. Several option/value pairs may be specified (the function Plot2D has a variable number of arguments).

Other options may be supported in the future.

The current implementation can deal with a singularity within the plotting range only if the function f(x) returns Infinity, -Infinity or Undefined at the singularity. If the function f(x) generates a numerical error and fails at a singularity, Plot2D will fail if one of the grid points falls on the singularity. (All grid points are generated by bisection so in principle the endpoints and the points parameter could be chosen to avoid numerical singularities.)

*WIN32

See also:
V , NFunction , Plot3DS .


Plot3DS -- three-dimensional (surface) plotting

Standard library
Calling format:
Plot3DS(f(x,y))
Plot3DS(f(x,y), a:b, c:d)
Plot3DS(f(x,y), a:b, c:d, option=value)
Plot3DS(f(x,y), a:b, c:d, option=value, ...)
Plot3DS(list, ...)

Parameters:
f(x,y) -- unevaluated expression containing two variables (function to be plotted)

list -- list of functions to plot

a, b, c, d -- numbers, plotting ranges in the x and y coordinates

option -- atom, option name

value -- atom, number or string (value of option)

Description:
The routine Plot3DS performs adaptive plotting of a function of two variables in the specified ranges. The result is presented as a surface given by the equation z=f(x,y). Several functions can be plotted at once, by giving a list of functions. Various plotting options can be specified. Output can be directed to a plotting program (the default is to use data), to a list of values.

The function parameter f(x,y) must evaluate to a Yacas expression containing at most two variables. (The variables do not have to be called x and y.) Also, N(f(x,y)) must evaluate to a real (not complex) numerical value when given numerical values of the arguments x, y. If the function f(x,y) does not satisfy these requirements, an error is raised.

Several functions may be specified as a list but they have to depend on the same symbolic variables, for example, {f(x,y), g(y,x)}, but not {f(x,y), g(a,b)}. The functions will be plotted on the same graph using the same coordinate ranges.

If you have defined a function which accepts a number but does not accept an undefined variable, Plot3DS will fail to plot it. Use NFunction to overcome this difficulty.

Data files are created in a temporary directory /tmp/plot.tmp/ unless otherwise requested. File names and other information is printed if InVerboseMode() returns True on using V().

The current algorithm uses Newton-Cotes cubatures and some heuristics for error estimation (see The Yacas book of algorithms, Chapter 3, Section 1 ). The initial rectangular grid of xpoints+1*ypoints+1 points is refined within any rectangle where the integral of f(x,y) is not approximated to the given precision by the existing grid.

Default plotting range is -5:5 in both coordinates. A range can also be specified with a variable name, e.g. x= -5:5 (note the mandatory space separating "=" and "-"). The variable name x should be the same as that used in the function f(x,y). If ranges are not given with variable names, the first variable encountered in the function f(x,y) is associated with the first of the two ranges.

Options are of the form option=value. Currently supported option names are "points", "xpoints", "ypoints", "precision", "depth", "output", "filename", "xrange", "yrange", "zrange". Option values are either numbers or special unevaluated atoms such as data. If you need to use the names of these atoms in your script, strings can be used (e.g. output="data"). Several option/value pairs may be specified (the function Plot3DS has a variable number of arguments).

Other options may be supported in the future.

The current implementation can deal with a singularity within the plotting range only if the function f(x,y) returns Infinity, -Infinity or Undefined at the singularity. If the function f(x,y) generates a numerical error and fails at a singularity, Plot3DS will fail only if one of the grid points falls on the singularity. (All grid points are generated by bisection so in principle the endpoints and the xpoints, ypoints parameters could be chosen to avoid numerical singularities.)

The filename option is optional if using graphical backends, but can be used to specify the location of the created data file.

*WIN32

Same limitations as Plot2D.

Examples:
In> Plot3DS(a*b^2)
Out> True;
In> V(Plot3DS(Sin(x)*Cos(y),x=0:20, y=0:20,depth=3))
CachedConstant: Info: constant Pi is being 
  recalculated at precision 10
CachedConstant: Info: constant Pi is being
  recalculated at precision 11
Plot3DS: using 1699  points for function Sin(x)*Cos(y)
Plot3DS: max. used 8 subdivisions for Sin(x)*Cos(y)
Plot3DS'datafile: created file '/tmp/plot.tmp/data1'
Out> True;

See also:
V , NFunction , Plot2D .


XmlExplodeTag -- convert XML strings to tag objects

Internal function
Calling format:
XmlExplodeTag(xmltext)
Parameters:
xmltext -- string containing some XML tokens

Description:
XmlExplodeTag parses the first XML token in xmltext and returns a Yacas expression.

The following subset of XML syntax is supported currently:

The tag options take the form paramname="value".

If given an XML tag, XmlExplodeTag returns a structure of the form XmlTag(name,params,type). In the returned object, name is the (capitalized) tag name, params is an assoc list with the options (key fields capitalized), and type can be either "Open", "Close" or "OpenClose".

If given a plain text string, the same string is returned.

Examples:
In> XmlExplodeTag("some plain text")
Out> "some plain text";
In> XmlExplodeTag("<a name=\"blah blah\"
  align=\"left\">")
Out> XmlTag("A",{{"ALIGN","left"},
  {"NAME","blah blah"}},"Open");
In> XmlExplodeTag("</p>")
Out> XmlTag("P",{},"Close");
In> XmlExplodeTag("<br/>")
Out> XmlTag("BR",{},"OpenClose");

See also:
XmlTokenizer .


DefaultTokenizer -- select the default syntax tokenizer for parsing the input


XmlTokenizer -- select an XML syntax tokenizer for parsing the input

Internal function
Calling format:
DefaultTokenizer()
XmlTokenizer()

Description:
A "tokenizer" is an internal routine in the kernel that parses the input into Yacas expressions. This affects all input typed in by a user at the prompt and also the input redirected from files or strings using FromFile and FromString and read using Read or ReadToken.

The Yacas environment currently supports some experimental tokenizers for various syntaxes. DefaultTokenizer switches to the tokenizer used for default Yacas syntax. XmlTokenizer switches to an XML syntax. Note that setting the tokenizer is a global side effect. One typically needs to switch back to the default tokenizer when finished reading the special syntax.

Care needs to be taken when kernel errors are raised during a non-default tokenizer operation (as with any global change in the environment). Errors need to be caught with the TrapError function. The error handler code should re-instate the default tokenizer, or else the user will be unable to continue the session (everything a user types will be parsed using a non-default tokenizer).

When reading XML syntax, the supported formats are the same as those of XmlExplodeTag. The parser does not validate anything in the XML input. After an XML token has been read in, it can be converted into an Yacas expression with XmlExplodeTag. Note that when reading XML, any plain text between tags is returned as one token. Any malformed XML will be treated as plain text.

Example:
In> [XmlTokenizer(); q:=ReadToken(); \
  DefaultTokenizer();q;]
<a>Out> <a>;

Note that:

See also:
OMRead , TrapError , XmlExplodeTag , ReadToken , FromFile , FromString .


OMForm -- convert Yacas expression to OpenMath


OMRead -- convert expression from OpenMath to Yacas expression

Standard library
Calling format:
OMForm(expression)
OMRead()

Parameters:
expression -- expression to convert

Description:
OMForm prints an OpenMath representation of the input parameter expression to standard output. OMRead reads an OpenMath expression from standard input and returns a normal Yacas expression that matches the input OpenMath expression.

If a Yacas symbol does not have a mapping defined by OMDef, it is translated to and from OpenMath as the OpenMath symbol in the CD "yacas" with the same name as it has in Yacas.

Example:
In> str:=ToString()OMForm(2+Sin(a*3))
Out> "<OMOBJ>
  <OMA>
    <OMS cd="arith1" name="plus"/>
    <OMI>2</OMI>
    <OMA>
      <OMS cd="transc1" name="sin"/>
      <OMA>
        <OMS cd="arith1" name="times"/>
        <OMV name="a"/>
        <OMI>3</OMI>
      </OMA>
    </OMA>
  </OMA>
</OMOBJ>
";
In> FromString(str)OMRead()
Out> 2+Sin(a*3);

In> OMForm(NotDefinedInOpenMath(2+3))
<OMOBJ>
  <OMA>
    <OMS cd="yacas" name="NotDefinedInOpenMath"/>
    <OMA>
      <OMS cd="arith1" name="plus"/>
      <OMI>2</OMI>
      <OMI>3</OMI>
    </OMA>
  </OMA>
</OMOBJ>
Out> True

See also:
XmlTokenizer , XmlExplodeTag , OMDef .


OMDef -- define translations from Yacas to OpenMath and vice-versa.

Standard library
Calling format:
OMDef(yacasForm, cd, name)
OMDef(yacasForm, cd, name, yacasToOM)
OMDef(yacasForm, cd, name, yacasToOM, omToYacas)

Parameters:
yacasForm -- string with the name of a Yacas symbol, or a Yacas expression

cd -- OpenMath Content Dictionary for the symbol

name -- OpenMath name for the symbol

yacasToOM -- rule for translating an application of that symbol in Yacas into an OpenMath expression

omToYacas -- rule for translating an OpenMath expression into an application of this symbol in Yacas

Description:
OMDef defines the translation rules for symbols between the Yacas representation and OpenMath. The first parameter, yacasForm, can be a string or an expression. The difference is that when giving an expression only the omToYacas translation is defined, and it uses the exact expression given. This is used for OpenMath symbols that must be translated into a whole subexpression in Yacas, such as set1:emptyset which gets translated to an empty list as follows:
In> OMDef( {}, "set1","emptyset" )
Out> True
In> FromString("<OMOBJ><OMS cd=\"set1\" name=\"emptyset\"/></OMOBJ> ")OMRead()
Out> {}
In> IsList(%)
Out> True
Otherwise, a symbol that is not inside an application (OMA) gets translated to the Yacas atom with the given name:
In> OMDef( "EmptySet", "set1","emptyset" )
Warning: the mapping for set1:emptyset was already defined as {} , but is redefined now as EmptySet
Out> True
In> FromString("<OMOBJ><OMS cd=\"set1\" name=\"emptyset\"/></OMOBJ> ")OMRead()
Out> EmptySet

The definitions for the symbols in the Yacas library are in the *.rep script subdirectories. In those modules for which the mappings are defined, there is a file called om.ys that contains the OMDef calls. Those files are loaded in openmath.rep/om.ys, so any new file must be added to the list there, at the end of the file.

A rule is represented as a list of expressions. Since both OM and Yacas expressions are actually lists, the syntax is the same in both directions. There are two template forms that are expanded before the translation:

They can appear anywhere in the rule as expressions or subexpressions.

Finally, several alternative rules can be specified by joining them with the | symbol, and each of them can be annotated with a post-predicate applied with the underscore _ symbol, in the style of Yacas' simplification rules. Only the first alternative rule that matches is applied, so the more specific rules must be written first.

There are special symbols recognized by OMForm to output OpenMath constructs that have no specific parallel in Yacas, such as an OpenMath symbol having a CD and name: Yacas symbols have only a name. Those special symbols are:

When translating from OpenMath to Yacas, we just store unknown symbols as OMS("cd", "name"). This way we don't have to bother defining bogus symbols for concepts that Yacas does not handle, and we can evaluate expressions that contain them.

Examples:
In> OMDef( "Sqrt" ,  "arith1", "root", { $, _1, 2 }, $(_1)_(_2=2) | (_1^(1/_2)) );
Out> True
In> OMForm(Sqrt(3))
<OMOBJ>
  <OMA>
    <OMS cd="arith1" name="root"/>
    <OMI>3</OMI>
    <OMI>2</OMI>
  </OMA>
</OMOBJ>
Out> True
In> FromString("<OMOBJ><OMA><OMS cd=\"arith1\" name=\"root\"/><OMI>16</OMI><OMI>2</OMI></OMA></OMOBJ> ")OMRead()
Out> Sqrt(16)
In> FromString("<OMOBJ><OMA><OMS cd=\"arith1\" name=\"root\"/><OMI>16</OMI><OMI>3</OMI></OMA></OMOBJ> ")OMRead()
Out> 16^(1/3)

In> OMDef("Limit", "limit1", "limit", \
      {  $, _2, OMS("limit1", "under"), OMBIND(OMS("fns1", "lambda"), OMBVAR(_1), _4) }_(_3=Left)  \
      |{ $, _2, OMS("limit1", "above"), OMBIND(OMS("fns1", "lambda"), OMBVAR(_1), _4) }_(_3=Right) \
      |{ $, _2, OMS("limit1", "both_sides"), OMBIND(OMS("fns1", "lambda"), OMBVAR(_1), _3) },      \
      { $, _{3,2,1}, _1, Left,  _{3,3}}_(_2=OMS("limit1", "below")) \
      |{$, _{3,2,1}, _1, Right, _{3,3}}_(_2=OMS("limit1", "above")) \
      |{$, _{3,2,1}, _1, _{3,3}}                                    \
     );
In> OMForm(Limit(x,0) Sin(x)/x)
<OMOBJ>
  <OMA>
    <OMS cd="limit1" name="limit"/>
    <OMI>0</OMI>
    <OMS cd="limit1" name="both_sides"/>
    <OMBIND>
      <OMS cd="fns1" name="lambda"/>
      <OMBVAR>
        <OMV name="x"/>
      </OMBVAR>
      <OMA>
        <OMS cd="arith1" name="divide"/>
        <OMA>
          <OMS cd="transc1" name="sin"/>
          <OMV name="x"/>
        </OMA>
        <OMV name="x"/>
      </OMA>
    </OMBIND>
  </OMA>
</OMOBJ>
Out> True
In> OMForm(Limit(x,0,Right) 1/x)
<OMOBJ>
  <OMA>
    <OMS cd="limit1" name="limit"/>
    <OMI>0</OMI>
    <OMS cd="limit1" name="above"/>
    <OMBIND>
      <OMS cd="fns1" name="lambda"/>
      <OMBVAR>
        <OMV name="x"/>
      </OMBVAR>
      <OMA>
        <OMS cd="arith1" name="divide"/>
        <OMI>1</OMI>
        <OMV name="x"/>
      </OMA>
    </OMBIND>
  </OMA>
</OMOBJ>
Out> True
In> FromString(ToString()OMForm(Limit(x,0,Right) 1/x))OMRead()
Out> Limit(x,0,Right)1/x
In> %
Out> Infinity

See also:
OMForm , OMRead .