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Function parser for C++ v2.8 by Warp.
=====================================
Optimization code contributed by Bisqwit (http://iki.fi/bisqwit/)
The usage license of this library is located at the end of this text file.
What's new in v2.8

 Put the compiletime options to a separate file fpconfig.hh.
 Added comparison operators "!=", "<=" and ">=".
 Added an epsilon value to the comparison operators (its value can be
changed in fpconfig.hh or it can be completely disabled there).
 Added unary not operator "!".
 Now userdefined functions can take 0 parameters.
 Added a maximum recursion level to the "eval()" function (definable in
(fpconfig.hh). Now "eval()" should never cause an infinite recursion.
(Note however, that it may still be relevant to disable it completely
because it is possible to write functions which take enormous amounts
of time to evaluate even when the maximum recursion level is not reached.)
 Separated the optimizer code to its own file (makes developement easier).
=============================================================================
 Preface
=============================================================================
Often people need to ask some mathematical expression from the user and
then evaluate values for that expression. The simplest example is a program
which draws the graphic of a userdefined function on screen.
This library adds Cstyle function string parsing to the program. This
means that you can evaluate the string "sqrt(1x^2+y^2)" with given values
of 'x' and 'y'.
The library is intended to be very fast. It bytecompiles the function
string at parse time and interpretes this bytecode at evaluation time.
The evaluation is straightforward and no recursions are done (uses stack
arithmetic).
Empirical tests show that it indeed is very fast (specially compared to
libraries which evaluate functions by just interpreting the raw function
string).
The library is made in ISO C++ and requires a standardconforming C++
compiler.
=============================================================================
 Usage
=============================================================================
To use the FunctionParser class, you have to include "fparser.hh" in
your source code files which use the FunctionParser class.
When compiling, you have to compile fparser.cc and fpoptimizer.cc and
link them to the main program. In some developement environments it's
enough to add those two files to your current project.
If you are not going to use the optimizer (ie. you have commented out
SUPPORT_OPTIMIZER in fpconfig.hh), you can leave the latter file out.
* Configuring the compilation:

There is a set of precompiler options in the fpconfig.hh file
which can be used for setting certain features on or off:
NO_ASINH : (Default on)
By default the library does not support the asinh(), acosh()
and atanh() functions because they are not part of the ISO C++
standard. If your compiler supports them and you want the
parser to support them as well, comment out this line.
DISABLE_EVAL : (Default off)
Even though the maximum recursion level of the eval() function
is limited, it is still possible to write functions which never
reach this maximum recursion level but take enormous amounts of
time to evaluate (this can be undesirable eg. in web serverside
applications).
Uncommenting this line will disable the eval() function completely,
thus removing the danger of exploitation.
Note that you can also disable eval() by specifying the
DISABLE_EVAL precompiler constant in your compiler (eg.
with DDISABLE_EVAL in gcc).
EVAL_MAX_REC_LEVEL : (Default 1000)
Sets the maximum recursion level allowed for eval().
SUPPORT_OPTIMIZER : (Default on)
If you are not going to use the Optimize() method, you can comment
this line out to speedup the compilation of fparser.cc a bit, as
well as making the binary a bit smaller. (Optimize() can still be
called, but it will not do anything.)
You can also disable the optimizer by specifying the
NO_SUPPORT_OPTIMIZER precompiler constant in your compiler
(eg. with DNO_SUPPORT_OPTIMIZER in gcc).
FP_EPSILON : (Default 1e14)
Epsilon value used in comparison operators.
If this line is commented out, then no epsilon will be used.
* Copying and assignment:

The class implements a safe copy constructor and assignment operator.
It uses the copyonwrite technique for efficiency. This means that
when copying or assigning a FunctionParser instance, the internal data
(which in some cases can be quite lengthy) is not immediately copied
but only when the contents of the copy (or the original) are changed.
This means that copying/assigning is a very fast operation, and if
the copies are never modified then actual data copying never happens
either.
The Eval() and EvalError() methods of the copy can be called without
the internal data being copied.
Calling Parse(), Optimize() or the userdefined constant/function adding
methods will cause a deepcopy.
(C++ basics: The copy constructor is called when a new FunctionParser
instance is initialized with another, ie. like:
FunctionParser fp2 = fp1; // or: FunctionParser fp2(fp1);
or when a function takes a FunctionParser instance as parameter, eg:
void foo(FunctionParser p) // takes an instance of FunctionParser
{ ... }
The assignment operator is called when a FunctionParser instance is
assigned to another, like "fp2 = fp1;".)
* Short descriptions of FunctionParser methods:

int Parse(const std::string& Function, const std::string& Vars,
bool useDegrees = false);
Parses the given function and compiles it to internal format.
Return value is 1 if successful, else the index value to the location
of the error.
const char* ErrorMsg(void) const;
Returns an error message corresponding to the error in Parse(), or 0 if
no such error occurred.
ParseErrorType GetParseErrorType() const;
Returns the type of parsing error which occurred. Possible return types
are described in the long description.
double Eval(const double* Vars);
Evaluates the function given to Parse().
int EvalError(void) const;
Returns 0 if no error happened in the previous call to Eval(), else an
error code >0.
void Optimize();
Tries to optimize the bytecode for faster evaluation.
bool AddConstant(const std::string& name, double value);
Add a constant to the parser. Returns false if the name of the constant
is invalid, else true.
bool AddFunction(const std::string& name,
double (*functionPtr)(const double*),
unsigned paramsAmount);
Add a userdefined function to the parser (as a function pointer).
Returns false if the name of the function is invalid, else true.
bool AddFunction(const std::string& name, FunctionParser&);
Add a userdefined function to the parser (as a FunctionParser instance).
Returns false if the name of the function is invalid, else true.
* Long descriptions of FunctionParser methods:


int Parse(const std::string& Function, const std::string& Vars,
bool useDegrees = false);

Parses the given function (and compiles it to internal format).
Destroys previous function. Following calls to Eval() will evaluate
the given function.
The strings given as parameters are not needed anymore after parsing.
Parameters:
Function : String containing the function to parse.
Vars : String containing the variable names, separated by commas.
Eg. "x,y", "VarX,VarY,VarZ,n" or "x1,x2,x3,x4,__VAR__".
useDegrees: (Optional.) Whether to use degrees or radians in
trigonometric functions. (Default: radians)
Variables can have any size and they are case sensitive (ie. "var",
"VAR" and "Var" are *different* variable names). Letters, digits and
underscores can be used in variable names, but the name of a variable
can't begin with a digit. Each variable name can appear only once in
the 'Vars' string. Function names are not legal variable names.
Using longer variable names causes no overhead whatsoever to the Eval()
method, so it's completely safe to use variable names of any size.
The third, optional parameter specifies whether angles should be
interpreted as radians or degrees in trigonometrical functions.
If not specified, the default value is radians.
Return values:
On success the function returns 1.
On error the function returns an index to where the error was found
(0 is the first character, 1 the second, etc). If the error was not
a parsing error returns an index to the end of the string + 1.
Example: parser.Parse("3*x+y", "x,y");

const char* ErrorMsg(void) const;

Returns a pointer to an error message string corresponding to the error
caused by Parse() (you can use this to print the proper error message to
the user). If no such error has occurred, returns 0.

ParseErrorType GetParseErrorType() const;

Returns the type of parse error which occurred.
This method can be used to get the error type if ErrorMsg() is not
enough for printing the error message. In other words, this can be
used for printing customized error messages (eg. in another language).
If the default error messages suffice, then this method doesn't need
to be called.
FunctionParser::ParseErrorType is an enumerated type inside the class
(ie. its values are accessed like "FunctionParser::SYNTAX_ERROR").
The possible values for FunctionParser::ParseErrorType are listed below,
along with their equivalent error message returned by the ErrorMsg()
method:
FP_NO_ERROR : If no error occurred in the previous call to Parse().
SYNTAX_ERROR : "Syntax error"
MISM_PARENTH : "Mismatched parenthesis"
MISSING_PARENTH : "Missing ')'"
EMPTY_PARENTH : "Empty parentheses"
EXPECT_OPERATOR : "Syntax error: Operator expected"
OUT_OF_MEMORY : "Not enough memory"
UNEXPECTED_ERROR : "An unexpected error occurred. Please make a full bug "
"report to the author"
INVALID_VARS : "Syntax error in parameter 'Vars' given to "
"FunctionParser::Parse()"
ILL_PARAMS_AMOUNT : "Illegal number of parameters to function"
PREMATURE_EOS : "Syntax error: Premature end of string"
EXPECT_PARENTH_FUNC: "Syntax error: Expecting ( after function"

double Eval(const double* Vars);

Evaluates the function given to Parse().
The array given as parameter must contain the same amount of values as
the amount of variables given to Parse(). Each value corresponds to each
variable, in the same order.
Return values:
On success returns the evaluated value of the function given to
Parse().
On error (such as division by 0) the return value is unspecified,
probably 0.
Example:
double Vars[] = {1, 2.5};
double result = parser.Eval(Vars);

int EvalError(void) const;

Used to test if the call to Eval() succeeded.
Return values:
If there was no error in the previous call to Eval(), returns 0,
else returns a positive value as follows:
1: division by zero
2: sqrt error (sqrt of a negative value)
3: log error (logarithm of a negative value)
4: trigonometric error (asin or acos of illegal value)
5: maximum recursion level in eval() reached

void Optimize();

This method can be called after calling the Parse() method. It will try
to simplify the internal bytecode so that it will evaluate faster (it
tries to reduce the amount of opcodes in the bytecode).
For example, the bytecode for the function "5+x*y25*4/8" will be
reduced to a bytecode equivalent to the function "x*y7.5" (the original
11 opcodes will be reduced to 5). Besides calculating constant expressions
(like in the example), it also performs other types of simplifications
with variable and function expressions.
This method is quite slow and the decision of whether to use it or
not should depend on the type of application. If a function is parsed
once and evaluated millions of times, then calling Optimize() may speedup
noticeably. However, if there are tons of functions to parse and each one
is evaluated once or just a few times, then calling Optimize() will only
slow down the program.
Also, if the original function is expected to be optimal, then calling
Optimize() would be useless.
Note: Currently this method does not make any checks (like Eval() does)
and thus things like "1/0" will cause undefined behaviour. (On the other
hand, if such expression is given to the parser, Eval() will always give
an error code, no matter what the parameters.) If caching this type of
errors is important, a workaround is to call Eval() once before calling
Optimize() and checking EvalError().
If the destination application is not going to use this method,
the compiler constant SUPPORT_OPTIMIZER can be undefined in fpconfig.hh
to make the library smaller (Optimize() can still be called, but it will
not do anything).
(If you are interested in seeing how this method optimizes the opcode,
you can call the PrintByteCode() method before and after the call to
Optimize() to see the difference.)

bool AddConstant(const std::string& name, double value);

This method can be used to add constants to the parser. Syntactically
constants are identical to variables (ie. they follow the same naming
rules and they can be used in the function string in the same way as
variables), but internally constants are directly replaced with their
value at parse time.
Constants used by a function must be added before calling Parse()
for that function. Constants are preserved between Parse() calls in
the current FunctionParser instance, so they don't need to be added
but once. (If you use the same constant in several instances of
FunctionParser, you will need to add it to all the instances separately.)
Constants can be added at any time and the value of old constants can
be changed, but new additions and changes will only have effect the next
time Parse() is called. (That is, changing the value of a constant
after calling Parse() and before calling Eval() will have no effect.)
The return value will be false if the 'name' of the constant was
illegal, else true. If the name was illegal, the method does nothing.
Example: parser.AddConstant("pi", 3.1415926535897932);
Now for example parser.Parse("x*pi", "x"); will be identical to the
call parser.Parse("x*3.1415926535897932", "x");

bool AddFunction(const std::string& name,
double (*functionPtr)(const double*),
unsigned paramsAmount);

This method can be used to add new functions to the parser. For example,
if you would like to add a function "sqr(A)" which squares the value
of A, you can do it with this method (so that you don't need to touch
the source code of the parser).
The method takes three parameters:
 The name of the function. The name follows the same naming conventions
as variable names.
 A C++ function, which will be called when evaluating the function
string (if the usergiven function is called there). The C++ function
must have the form:
double functionName(const double* params);
 The number of parameters the function takes. 0 is a valid value
in which case the function takes no parameters (such function
should simply ignore the double* it gets as a parameter).
The return value will be false if the given name was invalid (either it
did not follow the variable naming conventions, or the name was already
reserved), else true. If the return value is false, nothing is added.
Example:
Suppose we have a C++ function like this:
double Square(const double* p)
{
return p[0]*p[0];
}
Now we can add this function to the parser like this:
parser.AddFunction("sqr", Square, 1);
parser.Parse("2*sqr(x)", "x");
An example of a useful function taking no parameters is a function
returning a random value. For example:
double Rand(const double*)
{
return drand48();
}
parser.AddFunction("rand", Rand, 0);
IMPORTANT NOTE: If you use the Optimize() method, it will assume that
the usergiven function has no sideeffects, that is, it always
returns the same value for the same parameters. The optimizer will
optimize the function call away in some cases, making this assumption.
(The Rand() function given as example above is one such problematic case.)

bool AddFunction(const std::string& name, FunctionParser&);

This method is almost identical to the previous AddFunction(), but
instead of taking a C++ function, it takes another FunctionParser
instance.
There are some important restrictions on making a FunctionParser instance
call another:
 The FunctionParser instance given as parameter must be initialized
with a Parse() call before giving it as parameter. That is, if you
want to use the parser A in the parser B, you must call A.Parse()
before you can call B.AddFunction("name", A).
 The amount of variables in the FunctionParser instance given as
parameter must not change after it has been given to the AddFunction()
of another instance. Changing the number of variables will result in
malfunction.
 AddFunction() will fail (ie. return false) if a recursive loop is
formed. The method specifically checks that no such loop is built.
Example:
FunctionParser f1, f2;
f1.Parse("x*x", "x");
f2.AddFunction("sqr", f1);
This version of the AddFunction() method can be useful to eg. chain
usergiven functions. For example, ask the user for a function F1,
and then ask the user another function F2, but now the user can
call F1 in this second function if he wants (and so on with a third
function F3, where he can call F1 and F2, etc).
=============================================================================
 The function string
=============================================================================
The function string understood by the class is very similar to the Csyntax.
Arithmetic float expressions can be created from float literals, variables
or functions using the following operators in this order of precedence:
() expressions in parentheses first
A^B exponentiation (A raised to the power B)
A unary minus
!A unary logical not (result is 1 if int(A) is 0, else 0)
A*B A/B A%B multiplication, division and modulo
A+B AB addition and subtraction
A=B A!=B A<B A<=B A>B A>=B
comparison between A and B (result is either 0 or 1)
A&B result is 1 if int(A) and int(B) differ from 0, else 0
AB result is 1 if int(A) or int(B) differ from 0, else 0
Since the unary minus has higher precedence than any other operator, for
example the following expression is valid: x*y
The comparison operators use an epsilon value, so expressions which may
differ in very leastsignificant digits should work correctly. For example,
"0.1+0.1+0.1+0.1+0.1+0.1+0.1+0.1+0.1+0.1 = 1" should always return 1, and
the same comparison done with ">" or "<" should always return 0.
(The epsilon value can be configured in the fpconfig.hh file.)
Without epsilon this comparison probably returns the wrong value.
The class supports these functions:
abs(A) : Absolute value of A. If A is negative, returns A otherwise
returns A.
acos(A) : Arccosine of A. Returns the angle, measured in radians,
whose cosine is A.
acosh(A) : Same as acos() but for hyperbolic cosine.
asin(A) : Arcsine of A. Returns the angle, measured in radians, whose
sine is A.
asinh(A) : Same as asin() but for hyperbolic sine.
atan(A) : Arctangent of (A). Returns the angle, measured in radians,
whose tangent is (A).
atan2(A,B): Arctangent of A/B. The two main differences to atan() is
that it will return the right angle depending on the signs of
A and B (atan() can only return values betwen pi/2 and pi/2),
and that the return value of pi/2 and pi/2 are possible.
atanh(A) : Same as atan() but for hyperbolic tangent.
ceil(A) : Ceiling of A. Returns the smallest integer greater than A.
Rounds up to the next higher integer.
cos(A) : Cosine of A. Returns the cosine of the angle A, where A is
measured in radians.
cosh(A) : Same as cos() but for hyperbolic cosine.
cot(A) : Cotangent of A (equivalent to 1/tan(A)).
csc(A) : Cosecant of A (equivalent to 1/sin(A)).
eval(...) : This a recursive call to the function to be evaluated. The
number of parameters must be the same as the number of parameters
taken by the function. Must be called inside if() to avoid
infinite recursion.
exp(A) : Exponential of A. Returns the value of e raised to the power
A where e is the base of the natural logarithm, i.e. the
nonrepeating value approximately equal to 2.71828182846.
floor(A) : Floor of A. Returns the largest integer less than A. Rounds
down to the next lower integer.
if(A,B,C) : If int(A) differs from 0, the return value of this function is B,
else C. Only the parameter which needs to be evaluated is
evaluated, the other parameter is skipped; this makes it safe to
use eval() in them.
int(A) : Rounds A to the closest integer. 0.5 is rounded to 1.
log(A) : Natural (base e) logarithm of A.
log10(A) : Base 10 logarithm of A.
max(A,B) : If A>B, the result is A, else B.
min(A,B) : If A<B, the result is A, else B.
sec(A) : Secant of A (equivalent to 1/cos(A)).
sin(A) : Sine of A. Returns the sine of the angle A, where A is
measured in radians.
sinh(A) : Same as sin() but for hyperbolic sine.
sqrt(A) : Square root of A. Returns the value whose square is A.
tan(A) : Tangent of A. Returns the tangent of the angle A, where A
is measured in radians.
tanh(A) : Same as tan() but for hyperbolic tangent.
Examples of function string understood by the class:
"1+2"
"x1"
"sin(sqrt(x^2+y^2))"
"sqrt(XCoord*XCoord + YCoord*YCoord)"
An example of a recursive function is the factorial function:
"if(n>1, n*eval(n1), 1)"
Note that a recursive call has some overhead, which makes it a bit slower
than any other operation. It may be a good idea to avoid recursive functions
in very timecritical applications. Recursion also takes some memory, so
extremely deep recursions should be avoided (eg. millions of nested recursive
calls).
Also note that even though the maximum recursion level of eval() is
limited, it is possible to write functions which never reach that level
but still take enormous amounts of time to evaluate.
This can sometimes be undesirable because it is prone to exploitation,
but you can disable the eval() function completely in the fpconfig.hh file.
=============================================================================
 Contacting the author
=============================================================================
Any comments, bug reports, etc. should be sent to warp@iki.fi
=============================================================================
 The algorithm used in the library
=============================================================================
The whole idea behind the algorithm is to convert the regular infix
format (the regular syntax for mathematical operations in most languages,
like C and the input of the library) to postfix format. The postfix format
is also called stack arithmetic since an expression in postfix format
can be evaluated using a stack and operating with the top of the stack.
For example:
infix postfix
2+3 2 3 +
1+2+3 1 2 + 3 +
5*2+8/2 5 2 * 8 2 / +
(5+9)*3 5 9 + 3 *
The postfix notation should be read in this way:
Let's take for example the expression: 5 2 * 8 2 / +
 Put 5 on the stack
 Put 2 on the stack
 Multiply the two values on the top of the stack and put the result on
the stack (removing the two old values)
 Put 8 on the stack
 Put 2 on the stack
 Divide the two values on the top of the stack
 Add the two values on the top of the stack (which are in this case
the result of 5*2 and 8/2, that is, 10 and 4).
At the end there's only one value in the stack, and that value is the
result of the expression.
Why stack arithmetic?
The last example above can give you a hint.
In infix format operators have precedence and we have to use parentheses to
group operations with lower precedence to be calculated before operations
with higher precedence.
This causes a problem when evaluating an infix expression, specially
when converting it to byte code. For example in this kind of expression:
(x+1)/(y+2)
we have to calculate first the two additions before we can calculate the
division. We have to also keep counting parentheses, since there can be
a countless amount of nested parentheses. This usually means that you
have to do some type of recursion.
The most simple and efficient way of calculating this is to convert it
to postfix notation.
The postfix notation has the advantage that you can make all operations
in a straightforward way. You just evaluate the expression from left to
right, applying each operation directly and that's it. There are no
parentheses to worry about. You don't need recursion anywhere.
You have to keep a stack, of course, but that's extremely easily done.
Also you just operate with the top of the stack, which makes it very easy.
You never have to go deeper than 2 items in the stack.
And even better: Evaluating an expression in postfix format is never
slower than in infix format. All the contrary, in many cases it's a lot
faster (eg. because all parentheses are optimized away).
The above example could be expressed in postfix format:
x 1 + y 2 + /
The good thing about the postfix notation is also the fact that it can
be extremely easily expressed in bytecode form.
You only need a byte value for each operation, for each variable and
to push a constant to the stack.
Then you can interpret this bytecode straightforwardly. You just interpret
it byte by byte, from the beginning to the end. You never have to go back,
make loops or anything.
This is what makes bytecoded stack arithmetic so fast.
=============================================================================
Usage license:
=============================================================================
Copyright � 20032005 Juha Nieminen, Joel Yliluoma
This library is distributed under two distinct usage licenses depending
on the software ("Software" below) which uses the Function Parser library
("Library" below).
The reason for having two distinct usage licenses is to make the library
compatible with the GPL license while still being usable in other nonGPL
(even commercial) software.
A) If the Software using the Library is distributed under the GPL license,
then the Library can be used under the GPL license as well.
The Library will be under the GPL license only when used with the
Software. If the Library is separated from the Software and used in
another different software under a different license, then the Library
will have the B) license below.
Exception to the above: If the Library is modified for the GPL Software,
then the Library cannot be used with the B) license without the express
permission of the author of the modifications. A modified library will
be under the GPL license by default. That is, only the original,
unmodified version of the Library can be taken to another software
with the B) license below.
The author of the Software should provide an URL to the original
version of the Library if the one used in the Software has been
modified. (http://iki.fi/warp/FunctionParser/)
This text file must be distributed in its original intact form along
with the sources of the Library. (Documentation about possible
modifications to the library should be put in a different text file.)
B) If the Software using the Library is not distributed under the GPL
license but under any other license, then the following usage license
applies to the Library:
1. This library is free for noncommercial usage. You can do whatever you
like with it as long as you don't claim you made it yourself.
2. It is possible to use this library in a commercial program, but in this
case you MUST contact me first (warp@iki.fi) and ask express permission
for this. (Read explanation at the end of the file.)
If you are making a free program or a shareware program with just a
nominal price (5 US dollars or less), you don't have to ask for
permission.
In any case, I DON'T WANT MONEY for the usage of this library. It is
free, period.
3. You can make any modifications you want to it so that it conforms your
needs. If you make modifications to it, you have, of course, credits for
the modified parts.
4. If you use this library in your own program, you don't have to provide
the source code if you don't want to (ie. the source code of your program
or this library).
If you DO include the source code for this library, this text file
must be included in its original intact form.
5. If you distribute a program which uses this library, and specially if you
provide the source code, proper credits MUST be included. Trying to
obfuscate the fact that this library is not made by you or that it is
free is expressly prohibited. When crediting the usage of this library,
it's enough to include my name and email address, that is:
"Juha Nieminen (warp@iki.fi)". Also a URL to the library download page
would be nice, although not required. The official URL is:
http://iki.fi/warp/FunctionParser/
6. And the necessary "lawyer stuff":
The above copyright notice and this permission notice shall be
included in all copies or substantial portions of the Software.
The software is provided "as is", without warranty of any kind,
express or implied, including but not limited to the warranties of
merchantability, fitness for a particular purpose and noninfringement.
In no event shall the authors or copyright holders be liable for any
claim, damages or other liability, whether in an action of contract,
tort or otherwise, arising from, out of or in connection with the
software or the use or other dealings in the software.
 Explanation of the section 2 of the B) license above:
The section 2 tries to define "fair use" of the library in commercial
programs.
"Fair use" of the library means that the program is not heavily dependent
on the library, but the library only provides a minor secondary feature
to the program.
"Heavily dependent" means that the program depends so much on the library
that without it the functionality of the program would be seriously
degraded or the program would even become completely nonfunctional.
In other words: If the program does not depend heavily on the library,
that is, the library only provides a minor secondary feature which could
be removed without the program being degraded in any considerable way,
then it's OK to use the library in the commercial program.
If, however, the program depends so heavily on the library that
removing it would make the program nonfunctional or degrade its
functionality considerably, then it's NOT OK to use the library.
The ideology behind this is that it's not fair to use a free library
as a base for a commercial program, but it's fair if the library is
just a minor, unimportant extra.
If you are going to ask me for permission to use the library in a
commercial program, please describe the feature which the library will
be providing and how important it is to the program.
