This is a tutorial that documents GiNaC @value{VERSION}, an open
framework for symbolic computation within the C++ programming language.
-Copyright (C) 1999-2003 Johannes Gutenberg University Mainz, Germany
+Copyright (C) 1999-2004 Johannes Gutenberg University Mainz, Germany
Permission is granted to make and distribute verbatim copies of
this manual provided the copyright notice and this permission notice
@subtitle An open framework for symbolic computation within the C++ programming language
@subtitle @value{UPDATED}
@author The GiNaC Group:
-@author Christian Bauer, Alexander Frink, Richard Kreckel
+@author Christian Bauer, Alexander Frink, Richard Kreckel, Jens Vollinga
@page
@vskip 0pt plus 1filll
-Copyright @copyright{} 1999-2003 Johannes Gutenberg University Mainz, Germany
+Copyright @copyright{} 1999-2004 Johannes Gutenberg University Mainz, Germany
@sp 2
Permission is granted to make and distribute verbatim copies of
this manual provided the copyright notice and this permission notice
@section License
The GiNaC framework for symbolic computation within the C++ programming
-language is Copyright @copyright{} 1999-2003 Johannes Gutenberg
+language is Copyright @copyright{} 1999-2004 Johannes Gutenberg
University Mainz, Germany.
This program is free software; you can redistribute it and/or
* Matrices:: Matrices.
* Indexed objects:: Handling indexed quantities.
* Non-commutative objects:: Algebras with non-commutative products.
+* Hash Maps:: A faster alternative to std::map<>.
@end menu
hierarchy and describe the classes of objects that are handled by
@code{ex}.
+@subsection Note: Expressions and STL containers
+
+GiNaC expressions (@code{ex} objects) have value semantics (they can be
+assigned, reassigned and copied like integral types) but the operator
+@code{<} doesn't provide a well-defined ordering on them. In STL-speak,
+expressions are @samp{Assignable} but not @samp{LessThanComparable}.
+
+This implies that in order to use expressions in sorted containers such as
+@code{std::map<>} and @code{std::set<>} you have to supply a suitable
+comparison predicate. GiNaC provides such a predicate, called
+@code{ex_is_less}. For example, a set of expressions should be defined
+as @code{std::set<ex, ex_is_less>}.
+
+Unsorted containers such as @code{std::vector<>} and @code{std::list<>}
+don't pose a problem. A @code{std::vector<ex>} works as expected.
+
+@xref{Information About Expressions}, for more about comparing and ordering
+expressions.
+
@node Automatic evaluation, Error handling, Expressions, Basic Concepts
@c node-name, next, previous, up
@itemize @bullet
@item
-at most of complexity @math{O(n log n)}
+at most of complexity
+@tex
+$O(n\log n)$
+@end tex
+@ifnottex
+@math{O(n log n)}
+@end ifnottex
@item
algebraically correct, possibly except for a set of measure zero (e.g.
@math{x/x} is transformed to @math{1} although this is incorrect for @math{x=0})
The terms of sums and products (and some other things like the arguments of
symmetric functions, the indices of symmetric tensors etc.) are re-ordered
into a canonical form that is deterministic, but not lexicographical or in
-any other way easily guessable (it almost always depends on the number and
+any other way easy to guess (it almost always depends on the number and
order of the symbols you define). However, constructing the same expression
twice, either implicitly or explicitly, will always result in the same
canonical form.
The general rule is that when you construct expressions, GiNaC automatically
creates them in canonical form, which might differ from the form you typed in
your program. This may create some awkward looking output (@samp{-y+x} instead
-of @samp{y-x}) but allows for more efficient operation and usually yields
+of @samp{x-y}) but allows for more efficient operation and usually yields
some immediate simplifications.
@cindex @code{eval()}
that returns the order of the singularity (or 0 when the pole is
logarithmic or the order is undefined).
-When using GiNaC it is useful to arrange for exceptions to be catched in
+When using GiNaC it is useful to arrange for exceptions to be caught in
the main program even if you don't want to do any special error handling.
Otherwise whenever an error occurs in GiNaC, it will be delegated to the
default exception handler of your C++ compiler's run-time system which
@end ifnottex
@dots{}
@item @code{pseries} @tab Power Series, e.g. @math{x-1/6*x^3+1/120*x^5+O(x^7)}
-@item @code{function} @tab A symbolic function like @math{sin(2*x)}
+@item @code{function} @tab A symbolic function like
+@tex
+$\sin 2x$
+@end tex
+@ifnottex
+@math{sin(2*x)}
+@end ifnottex
@item @code{lst} @tab Lists of expressions @{@math{x}, @math{2*y}, @math{3+z}@}
@item @code{matrix} @tab @math{m}x@math{n} matrices of expressions
@item @code{relational} @tab A relation like the identity @math{x}@code{==}@math{y}
@cindex hierarchy of classes
@cindex atom
-Symbols are for symbolic manipulation what atoms are for chemistry. You
-can declare objects of class @code{symbol} as any other object simply by
-saying @code{symbol x,y;}. There is, however, a catch in here having to
-do with the fact that C++ is a compiled language. The information about
-the symbol's name is thrown away by the compiler but at a later stage
-you may want to print expressions holding your symbols. In order to
-avoid confusion GiNaC's symbols are able to know their own name. This
-is accomplished by declaring its name for output at construction time in
-the fashion @code{symbol x("x");}. If you declare a symbol using the
-default constructor (i.e. without string argument) the system will deal
-out a unique name. That name may not be suitable for printing but for
-internal routines when no output is desired it is often enough. We'll
-come across examples of such symbols later in this tutorial.
-
-This implies that the strings passed to symbols at construction time may
-not be used for comparing two of them. It is perfectly legitimate to
-write @code{symbol x("x"),y("x");} but it is likely to lead into
-trouble. Here, @code{x} and @code{y} are different symbols and
-statements like @code{x-y} will not be simplified to zero although the
-output @code{x-x} looks funny. Such output may also occur when there
-are two different symbols in two scopes, for instance when you call a
-function that declares a symbol with a name already existent in a symbol
-in the calling function. Again, comparing them (using @code{operator==}
-for instance) will always reveal their difference. Watch out, please.
+Symbolic indeterminates, or @dfn{symbols} for short, are for symbolic
+manipulation what atoms are for chemistry.
+
+A typical symbol definition looks like this:
+@example
+symbol x("x");
+@end example
+
+This definition actually contains three very different things:
+@itemize
+@item a C++ variable named @code{x}
+@item a @code{symbol} object stored in this C++ variable; this object
+ represents the symbol in a GiNaC expression
+@item the string @code{"x"} which is the name of the symbol, used (almost)
+ exclusively for printing expressions holding the symbol
+@end itemize
+
+Symbols have an explicit name, supplied as a string during construction,
+because in C++, variable names can't be used as values, and the C++ compiler
+throws them away during compilation.
+
+It is possible to omit the symbol name in the definition:
+@example
+symbol x;
+@end example
+
+In this case, GiNaC will assign the symbol an internal, unique name of the
+form @code{symbolNNN}. This won't affect the usability of the symbol but
+the output of your calculations will become more readable if you give your
+symbols sensible names (for intermediate expressions that are only used
+internally such anonymous symbols can be quite useful, however).
+
+Now, here is one important property of GiNaC that differentiates it from
+other computer algebra programs you may have used: GiNaC does @emph{not} use
+the names of symbols to tell them apart, but a (hidden) serial number that
+is unique for each newly created @code{symbol} object. In you want to use
+one and the same symbol in different places in your program, you must only
+create one @code{symbol} object and pass that around. If you create another
+symbol, even if it has the same name, GiNaC will treat it as a different
+indeterminate.
+
+Observe:
+@example
+ex f(int n)
+@{
+ symbol x("x");
+ return pow(x, n);
+@}
+
+int main()
+@{
+ symbol x("x");
+ ex e = f(6);
+
+ cout << e << endl;
+ // prints "x^6" which looks right, but...
+
+ cout << e.degree(x) << endl;
+ // ...this doesn't work. The symbol "x" here is different from the one
+ // in f() and in the expression returned by f(). Consequently, it
+ // prints "0".
+@}
+@end example
+
+One possibility to ensure that @code{f()} and @code{main()} use the same
+symbol is to pass the symbol as an argument to @code{f()}:
+@example
+ex f(int n, const ex & x)
+@{
+ return pow(x, n);
+@}
+
+int main()
+@{
+ symbol x("x");
+
+ // Now, f() uses the same symbol.
+ ex e = f(6, x);
+
+ cout << e.degree(x) << endl;
+ // prints "6", as expected
+@}
+@end example
+
+Another possibility would be to define a global symbol @code{x} that is used
+by both @code{f()} and @code{main()}. If you are using global symbols and
+multiple compilation units you must take special care, however. Suppose
+that you have a header file @file{globals.h} in your program that defines
+a @code{symbol x("x");}. In this case, every unit that includes
+@file{globals.h} would also get its own definition of @code{x} (because
+header files are just inlined into the source code by the C++ preprocessor),
+and hence you would again end up with multiple equally-named, but different,
+symbols. Instead, the @file{globals.h} header should only contain a
+@emph{declaration} like @code{extern symbol x;}, with the definition of
+@code{x} moved into a C++ source file such as @file{globals.cpp}.
+
+A different approach to ensuring that symbols used in different parts of
+your program are identical is to create them with a @emph{factory} function
+like this one:
+@example
+const symbol & get_symbol(const string & s)
+@{
+ static map<string, symbol> directory;
+ map<string, symbol>::iterator i = directory.find(s);
+ if (i != directory.end())
+ return i->second;
+ else
+ return directory.insert(make_pair(s, symbol(s))).first->second;
+@}
+@end example
+
+This function returns one newly constructed symbol for each name that is
+passed in, and it returns the same symbol when called multiple times with
+the same name. Using this symbol factory, we can rewrite our example like
+this:
+@example
+ex f(int n)
+@{
+ return pow(get_symbol("x"), n);
+@}
+
+int main()
+@{
+ ex e = f(6);
+
+ // Both calls of get_symbol("x") yield the same symbol.
+ cout << e.degree(get_symbol("x")) << endl;
+ // prints "6"
+@}
+@end example
+
+Instead of creating symbols from strings we could also have
+@code{get_symbol()} take, for example, an integer number as its argument.
+In this case, we would probably want to give the generated symbols names
+that include this number, which can be accomplished with the help of an
+@code{ostringstream}.
+
+In general, if you're getting weird results from GiNaC such as an expression
+@samp{x-x} that is not simplified to zero, you should check your symbol
+definitions.
+
+As we said, the names of symbols primarily serve for purposes of expression
+output. But there are actually two instances where GiNaC uses the names for
+identifying symbols: When constructing an expression from a string, and when
+recreating an expression from an archive (@pxref{Input/Output}).
+
+In addition to its name, a symbol may contain a special string that is used
+in LaTeX output:
+@example
+symbol x("x", "\\Box");
+@end example
+
+This creates a symbol that is printed as "@code{x}" in normal output, but
+as "@code{\Box}" in LaTeX code (@xref{Input/Output}, for more
+information about the different output formats of expressions in GiNaC).
+GiNaC automatically creates proper LaTeX code for symbols having names of
+greek letters (@samp{alpha}, @samp{mu}, etc.).
@cindex @code{subs()}
-Although symbols can be assigned expressions for internal reasons, you
-should not do it (and we are not going to tell you how it is done). If
-you want to replace a symbol with something else in an expression, you
-can use the expression's @code{.subs()} method (@pxref{Substituting Expressions}).
+Symbols in GiNaC can't be assigned values. If you need to store results of
+calculations and give them a name, use C++ variables of type @code{ex}.
+If you want to replace a symbol in an expression with something else, you
+can invoke the expression's @code{.subs()} method
+(@pxref{Substituting Expressions}).
+
+@cindex @code{realsymbol()}
+By default, symbols are expected to stand in for complex values, i.e. they live
+in the complex domain. As a consequence, operations like complex conjugation,
+for example (@pxref{Complex Conjugation}), do @emph{not} evaluate if applied
+to such symbols. Likewise @code{log(exp(x))} does not evaluate to @code{x},
+because of the unknown imaginary part of @code{x}.
+On the other hand, if you are sure that your symbols will hold only real values, you
+would like to have such functions evaluated. Therefore GiNaC allows you to specify
+the domain of the symbol. Instead of @code{symbol x("x");} you can write
+@code{realsymbol x("x");} to tell GiNaC that @code{x} stands in for real values.
@node Numbers, Constants, Symbols, Basic Concepts
@end multitable
@end cartouche
+@subsection Numeric functions
+
+The following functions can be applied to @code{numeric} objects and will be
+evaluated immediately:
+
+@cartouche
+@multitable @columnfractions .30 .70
+@item @strong{Name} @tab @strong{Function}
+@item @code{inverse(z)}
+@tab returns @math{1/z}
+@cindex @code{inverse()} (numeric)
+@item @code{pow(a, b)}
+@tab exponentiation @math{a^b}
+@item @code{abs(z)}
+@tab absolute value
+@item @code{real(z)}
+@tab real part
+@cindex @code{real()}
+@item @code{imag(z)}
+@tab imaginary part
+@cindex @code{imag()}
+@item @code{csgn(z)}
+@tab complex sign (returns an @code{int})
+@item @code{numer(z)}
+@tab numerator of rational or complex rational number
+@item @code{denom(z)}
+@tab denominator of rational or complex rational number
+@item @code{sqrt(z)}
+@tab square root
+@item @code{isqrt(n)}
+@tab integer square root
+@cindex @code{isqrt()}
+@item @code{sin(z)}
+@tab sine
+@item @code{cos(z)}
+@tab cosine
+@item @code{tan(z)}
+@tab tangent
+@item @code{asin(z)}
+@tab inverse sine
+@item @code{acos(z)}
+@tab inverse cosine
+@item @code{atan(z)}
+@tab inverse tangent
+@item @code{atan(y, x)}
+@tab inverse tangent with two arguments
+@item @code{sinh(z)}
+@tab hyperbolic sine
+@item @code{cosh(z)}
+@tab hyperbolic cosine
+@item @code{tanh(z)}
+@tab hyperbolic tangent
+@item @code{asinh(z)}
+@tab inverse hyperbolic sine
+@item @code{acosh(z)}
+@tab inverse hyperbolic cosine
+@item @code{atanh(z)}
+@tab inverse hyperbolic tangent
+@item @code{exp(z)}
+@tab exponential function
+@item @code{log(z)}
+@tab natural logarithm
+@item @code{Li2(z)}
+@tab dilogarithm
+@item @code{zeta(z)}
+@tab Riemann's zeta function
+@item @code{tgamma(z)}
+@tab gamma function
+@item @code{lgamma(z)}
+@tab logarithm of gamma function
+@item @code{psi(z)}
+@tab psi (digamma) function
+@item @code{psi(n, z)}
+@tab derivatives of psi function (polygamma functions)
+@item @code{factorial(n)}
+@tab factorial function @math{n!}
+@item @code{doublefactorial(n)}
+@tab double factorial function @math{n!!}
+@cindex @code{doublefactorial()}
+@item @code{binomial(n, k)}
+@tab binomial coefficients
+@item @code{bernoulli(n)}
+@tab Bernoulli numbers
+@cindex @code{bernoulli()}
+@item @code{fibonacci(n)}
+@tab Fibonacci numbers
+@cindex @code{fibonacci()}
+@item @code{mod(a, b)}
+@tab modulus in positive representation (in the range @code{[0, abs(b)-1]} with the sign of b, or zero)
+@cindex @code{mod()}
+@item @code{smod(a, b)}
+@tab modulus in symmetric representation (in the range @code{[-iquo(abs(b)-1, 2), iquo(abs(b), 2)]})
+@cindex @code{smod()}
+@item @code{irem(a, b)}
+@tab integer remainder (has the sign of @math{a}, or is zero)
+@cindex @code{irem()}
+@item @code{irem(a, b, q)}
+@tab integer remainder and quotient, @code{irem(a, b, q) == a-q*b}
+@item @code{iquo(a, b)}
+@tab integer quotient
+@cindex @code{iquo()}
+@item @code{iquo(a, b, r)}
+@tab integer quotient and remainder, @code{r == a-iquo(a, b)*b}
+@item @code{gcd(a, b)}
+@tab greatest common divisor
+@item @code{lcm(a, b)}
+@tab least common multiple
+@end multitable
+@end cartouche
+
+Most of these functions are also available as symbolic functions that can be
+used in expressions (@pxref{Mathematical functions}) or, like @code{gcd()},
+as polynomial algorithms.
+
+@subsection Converting numbers
+
+Sometimes it is desirable to convert a @code{numeric} object back to a
+built-in arithmetic type (@code{int}, @code{double}, etc.). The @code{numeric}
+class provides a couple of methods for this purpose:
+
+@cindex @code{to_int()}
+@cindex @code{to_long()}
+@cindex @code{to_double()}
+@cindex @code{to_cl_N()}
+@example
+int numeric::to_int() const;
+long numeric::to_long() const;
+double numeric::to_double() const;
+cln::cl_N numeric::to_cl_N() const;
+@end example
+
+@code{to_int()} and @code{to_long()} only work when the number they are
+applied on is an exact integer. Otherwise the program will halt with a
+message like @samp{Not a 32-bit integer}. @code{to_double()} applied on a
+rational number will return a floating-point approximation. Both
+@code{to_int()/to_long()} and @code{to_double()} discard the imaginary
+part of complex numbers.
+
@node Constants, Fundamental containers, Numbers, Basic Concepts
@c node-name, next, previous, up
The GiNaC class @code{lst} serves for holding a @dfn{list} of arbitrary
expressions. They are not as ubiquitous as in many other computer algebra
packages, but are sometimes used to supply a variable number of arguments of
-the same type to GiNaC methods such as @code{subs()} and @code{to_rational()},
-so you should have a basic understanding of them.
+the same type to GiNaC methods such as @code{subs()} and some @code{matrix}
+constructors, so you should have a basic understanding of them.
-Lists of up to 16 expressions can be directly constructed from single
+Lists can be constructed by assigning a comma-separated sequence of
expressions:
@example
@{
symbol x("x"), y("y");
- lst l(x, 2, y, x+y);
- // now, l is a list holding the expressions 'x', '2', 'y', and 'x+y'
+ lst l;
+ l = x, 2, y, x+y;
+ // now, l is a list holding the expressions 'x', '2', 'y', and 'x+y',
+ // in that order
+ ...
+@end example
+
+There are also constructors that allow direct creation of lists of up to
+16 expressions, which is often more convenient but slightly less efficient:
+
+@example
+ ...
+ // This produces the same list 'l' as above:
+ // lst l(x, 2, y, x+y);
+ // lst l = lst(x, 2, y, x+y);
...
@end example
@example
...
// print the elements of the list (requires #include <iterator>)
- copy(l.begin(), l.end(), ostream_iterator<ex>(cout, "\n"));
+ std::copy(l.begin(), l.end(), ostream_iterator<ex>(cout, "\n"));
// sum up the elements of the list (requires #include <numeric>)
- ex sum = accumulate(l.begin(), l.end(), ex(0));
+ ex sum = std::accumulate(l.begin(), l.end(), ex(0));
cout << sum << endl; // prints '2+2*x+2*y'
...
@end example
@example
...
- lst l1(x, 2, y, x+y);
- lst l2(2, x+y, x, y);
+ lst l1, l2;
+ l1 = x, 2, y, x+y;
+ l2 = 2, x+y, x, y;
l1.sort();
l2.sort();
// l1 and l2 are now equal
@example
...
- lst l3(x, 2, 2, 2, y, x+y, y+x);
+ lst l3;
+ l3 = x, 2, 2, 2, y, x+y, y+x;
l3.unique(); // l3 is now @{x, 2, y, x+y@}
@}
@end example
second one in the range 0@dots{}@math{n-1}.
There are a couple of ways to construct matrices, with or without preset
-elements:
+elements. The constructor
+
+@example
+matrix::matrix(unsigned r, unsigned c);
+@end example
+
+creates a matrix with @samp{r} rows and @samp{c} columns with all elements
+set to zero.
+
+The fastest way to create a matrix with preinitialized elements is to assign
+a list of comma-separated expressions to an empty matrix (see below for an
+example). But you can also specify the elements as a (flat) list with
+
+@example
+matrix::matrix(unsigned r, unsigned c, const lst & l);
+@end example
+
+The function
@cindex @code{lst_to_matrix()}
+@example
+ex lst_to_matrix(const lst & l);
+@end example
+
+constructs a matrix from a list of lists, each list representing a matrix row.
+
+There is also a set of functions for creating some special types of
+matrices:
+
@cindex @code{diag_matrix()}
@cindex @code{unit_matrix()}
@cindex @code{symbolic_matrix()}
@example
-matrix::matrix(unsigned r, unsigned c);
-matrix::matrix(unsigned r, unsigned c, const lst & l);
-ex lst_to_matrix(const lst & l);
ex diag_matrix(const lst & l);
ex unit_matrix(unsigned x);
ex unit_matrix(unsigned r, unsigned c);
ex symbolic_matrix(unsigned r, unsigned c, const string & base_name, const string & tex_base_name);
@end example
-The first two functions are @code{matrix} constructors which create a matrix
-with @samp{r} rows and @samp{c} columns. The matrix elements can be
-initialized from a (flat) list of expressions @samp{l}. Otherwise they are
-all set to zero. The @code{lst_to_matrix()} function constructs a matrix
-from a list of lists, each list representing a matrix row. @code{diag_matrix()}
-constructs a diagonal matrix given the list of diagonal elements.
-@code{unit_matrix()} creates an @samp{x} by @samp{x} (or @samp{r} by @samp{c})
-unit matrix. And finally, @code{symbolic_matrix} constructs a matrix filled
-with newly generated symbols made of the specified base name and the
-position of each element in the matrix.
+@code{diag_matrix()} constructs a diagonal matrix given the list of diagonal
+elements. @code{unit_matrix()} creates an @samp{x} by @samp{x} (or @samp{r}
+by @samp{c}) unit matrix. And finally, @code{symbolic_matrix} constructs a
+matrix filled with newly generated symbols made of the specified base name
+and the position of each element in the matrix.
Matrix elements can be accessed and set using the parenthesis (function call)
operator:
the @code{op()} method. But C++-style subscripting with square brackets
@samp{[]} is not available.
-Here are a couple of examples of constructing matrices:
+Here are a couple of examples for constructing matrices:
@example
@{
symbol a("a"), b("b");
matrix M(2, 2);
- M(0, 0) = a;
- M(1, 1) = b;
+ M = a, 0,
+ 0, b;
cout << M << endl;
// -> [[a,0],[0,b]]
+ matrix M2(2, 2);
+ M2(0, 0) = a;
+ M2(1, 1) = b;
+ cout << M2 << endl;
+ // -> [[a,0],[0,b]]
+
cout << matrix(2, 2, lst(a, 0, 0, b)) << endl;
// -> [[a,0],[0,b]]
@example
@{
- matrix A(2, 2, lst(1, 2, 3, 4));
- matrix B(2, 2, lst(-1, 0, 2, 1));
- matrix C(2, 2, lst(8, 4, 2, 1));
+ matrix A(2, 2), B(2, 2), C(2, 2);
+ A = 1, 2,
+ 3, 4;
+ B = -1, 0,
+ 2, 1;
+ C = 8, 4,
+ 2, 1;
matrix result = A.mul(B).sub(C.mul_scalar(2));
cout << result << endl;
general.
The @code{matrix} class provides a couple of additional methods for
-computing determinants, traces, and characteristic polynomials:
+computing determinants, traces, characteristic polynomials and ranks:
@cindex @code{determinant()}
@cindex @code{trace()}
@cindex @code{charpoly()}
+@cindex @code{rank()}
@example
ex matrix::determinant(unsigned algo=determinant_algo::automatic) const;
ex matrix::trace() const;
-ex matrix::charpoly(const symbol & lambda) const;
+ex matrix::charpoly(const ex & lambda) const;
+unsigned matrix::rank() const;
@end example
The @samp{algo} argument of @code{determinant()} allows to select
algorithm that is likely (but not guaranteed) to give the result most
quickly.
-@cindex @code{inverse()}
+@cindex @code{inverse()} (matrix)
@cindex @code{solve()}
Matrices may also be inverted using the @code{ex matrix::inverse()}
method and linear systems may be solved with:
symbol x("x"), y("y");
// A is a 2x2 matrix, X is a 2x1 vector
- matrix A(2, 2, lst(1, 2, 3, 4)), X(2, 1, lst(x, y));
+ matrix A(2, 2), X(2, 1);
+ A = 1, 2,
+ 3, 4;
+ X = x, y;
cout << indexed(A, i, i) << endl;
// -> 5
of the metric tensor.
-@node Non-commutative objects, Methods and Functions, Indexed objects, Basic Concepts
+@node Non-commutative objects, Hash Maps, Indexed objects, Basic Concepts
@c node-name, next, previous, up
@section Non-commutative objects
e = canonicalize_clifford(e);
cout << e << endl;
- // -> 2*eta~mu~nu
+ // -> 2*ONE*eta~mu~nu
@}
@end example
@end example
-@node Methods and Functions, Information About Expressions, Non-commutative objects, Top
+@node Hash Maps, Methods and Functions, Non-commutative objects, Basic Concepts
+@c node-name, next, previous, up
+@section Hash Maps
+@cindex hash maps
+@cindex @code{exhashmap} (class)
+
+For your convenience, GiNaC offers the container template @code{exhashmap<T>}
+that can be used as a drop-in replacement for the STL
+@code{std::map<ex, T, ex_is_less>}, using hash tables to provide faster,
+typically constant-time, element look-up than @code{map<>}.
+
+@code{exhashmap<>} supports all @code{map<>} members and operations, with the
+following differences:
+
+@itemize @bullet
+@item
+no @code{lower_bound()} and @code{upper_bound()} methods
+@item
+no reverse iterators, no @code{rbegin()}/@code{rend()}
+@item
+no @code{operator<(exhashmap, exhashmap)}
+@item
+the comparison function object @code{key_compare} is hardcoded to
+@code{ex_is_less}
+@item
+the constructor @code{exhashmap(size_t n)} allows specifying the minimum
+initial hash table size (the actual table size after construction may be
+larger than the specified value)
+@item
+the method @code{size_t bucket_count()} returns the current size of the hash
+table
+@item
+@code{insert()} and @code{erase()} operations invalidate all iterators
+@end itemize
+
+
+@node Methods and Functions, Information About Expressions, Hash Maps, Top
@c node-name, next, previous, up
@chapter Methods and Functions
@cindex polynomial
@menu
* Information About Expressions::
+* Numerical Evaluation::
* Substituting Expressions::
* Pattern Matching and Advanced Substitutions::
* Applying a Function on Subexpressions::
* Series Expansion:: Taylor and Laurent expansion.
* Symmetrization::
* Built-in Functions:: List of predefined mathematical functions.
+* Multiple polylogarithms::
+* Complex Conjugation::
+* Built-in Functions:: List of predefined mathematical functions.
* Solving Linear Systems of Equations::
* Input/Output:: Input and output of expressions.
@end menu
-@node Information About Expressions, Substituting Expressions, Methods and Functions, Methods and Functions
+@node Information About Expressions, Numerical Evaluation, Methods and Functions, Methods and Functions
@c node-name, next, previous, up
@section Getting information about expressions
@multitable @columnfractions .30 .70
@item @strong{Flag} @tab @strong{Returns true if the object is@dots{}}
@item @code{numeric}
-@tab @dots{}a number (same as @code{is_<numeric>(...)})
+@tab @dots{}a number (same as @code{is_a<numeric>(...)})
@item @code{real}
@tab @dots{}a real integer, rational or float (i.e. is not complex)
@item @code{rational}
@subsection Accessing subexpressions
-@cindex @code{nops()}
-@cindex @code{op()}
@cindex container
-@cindex @code{relational} (class)
-GiNaC provides the two methods
+Many GiNaC classes, like @code{add}, @code{mul}, @code{lst}, and
+@code{function}, act as containers for subexpressions. For example, the
+subexpressions of a sum (an @code{add} object) are the individual terms,
+and the subexpressions of a @code{function} are the function's arguments.
+
+@cindex @code{nops()}
+@cindex @code{op()}
+GiNaC provides several ways of accessing subexpressions. The first way is to
+use the two methods
@example
size_t ex::nops();
ex ex::op(size_t i);
@end example
-for accessing the subexpressions in the container-like GiNaC classes like
-@code{add}, @code{mul}, @code{lst}, and @code{function}. @code{nops()}
-determines the number of subexpressions (@samp{operands}) contained, while
-@code{op()} returns the @code{i}-th (0..@code{nops()-1}) subexpression.
-In the case of a @code{power} object, @code{op(0)} will return the basis
-and @code{op(1)} the exponent. For @code{indexed} objects, @code{op(0)}
-is the base expression and @code{op(i)}, @math{i>0} are the indices.
+@code{nops()} determines the number of subexpressions (operands) contained
+in the expression, while @code{op(i)} returns the @code{i}-th
+(0..@code{nops()-1}) subexpression. In the case of a @code{power} object,
+@code{op(0)} will return the basis and @code{op(1)} the exponent. For
+@code{indexed} objects, @code{op(0)} is the base expression and @code{op(i)},
+@math{i>0} are the indices.
+
+@cindex iterators
+@cindex @code{const_iterator}
+The second way to access subexpressions is via the STL-style random-access
+iterator class @code{const_iterator} and the methods
+
+@example
+const_iterator ex::begin();
+const_iterator ex::end();
+@end example
+
+@code{begin()} returns an iterator referring to the first subexpression;
+@code{end()} returns an iterator which is one-past the last subexpression.
+If the expression has no subexpressions, then @code{begin() == end()}. These
+iterators can also be used in conjunction with non-modifying STL algorithms.
+
+Here is an example that (non-recursively) prints the subexpressions of a
+given expression in three different ways:
+
+@example
+@{
+ ex e = ...
+
+ // with nops()/op()
+ for (size_t i = 0; i != e.nops(); ++i)
+ cout << e.op(i) << endl;
+
+ // with iterators
+ for (const_iterator i = e.begin(); i != e.end(); ++i)
+ cout << *i << endl;
+
+ // with iterators and STL copy()
+ std::copy(e.begin(), e.end(), std::ostream_iterator<ex>(cout, "\n"));
+@}
+@end example
+
+@cindex @code{const_preorder_iterator}
+@cindex @code{const_postorder_iterator}
+@code{op()}/@code{nops()} and @code{const_iterator} only access an
+expression's immediate children. GiNaC provides two additional iterator
+classes, @code{const_preorder_iterator} and @code{const_postorder_iterator},
+that iterate over all objects in an expression tree, in preorder or postorder,
+respectively. They are STL-style forward iterators, and are created with the
+methods
+
+@example
+const_preorder_iterator ex::preorder_begin();
+const_preorder_iterator ex::preorder_end();
+const_postorder_iterator ex::postorder_begin();
+const_postorder_iterator ex::postorder_end();
+@end example
+
+The following example illustrates the differences between
+@code{const_iterator}, @code{const_preorder_iterator}, and
+@code{const_postorder_iterator}:
+
+@example
+@{
+ symbol A("A"), B("B"), C("C");
+ ex e = lst(lst(A, B), C);
+
+ std::copy(e.begin(), e.end(),
+ std::ostream_iterator<ex>(cout, "\n"));
+ // @{A,B@}
+ // C
+
+ std::copy(e.preorder_begin(), e.preorder_end(),
+ std::ostream_iterator<ex>(cout, "\n"));
+ // @{@{A,B@},C@}
+ // @{A,B@}
+ // A
+ // B
+ // C
+
+ std::copy(e.postorder_begin(), e.postorder_end(),
+ std::ostream_iterator<ex>(cout, "\n"));
+ // A
+ // B
+ // @{A,B@}
+ // C
+ // @{@{A,B@},C@}
+@}
+@end example
-The left-hand and right-hand side expressions of objects of class
-@code{relational} (and only of these) can also be accessed with the methods
+@cindex @code{relational} (class)
+Finally, the left-hand side and right-hand side expressions of objects of
+class @code{relational} (and only of these) can also be accessed with the
+methods
@example
ex ex::lhs();
for checking whether one expression is equal to another, or equal to zero,
respectively.
-@strong{Warning:} You will also find an @code{ex::compare()} method in the
-GiNaC header files. This method is however only to be used internally by
-GiNaC to establish a canonical sort order for terms, and using it to compare
-expressions will give very surprising results.
+
+@subsection Ordering expressions
+@cindex @code{ex_is_less} (class)
+@cindex @code{ex_is_equal} (class)
+@cindex @code{compare()}
+
+Sometimes it is necessary to establish a mathematically well-defined ordering
+on a set of arbitrary expressions, for example to use expressions as keys
+in a @code{std::map<>} container, or to bring a vector of expressions into
+a canonical order (which is done internally by GiNaC for sums and products).
+
+The operators @code{<}, @code{>} etc. described in the last section cannot
+be used for this, as they don't implement an ordering relation in the
+mathematical sense. In particular, they are not guaranteed to be
+antisymmetric: if @samp{a} and @samp{b} are different expressions, and
+@code{a < b} yields @code{false}, then @code{b < a} doesn't necessarily
+yield @code{true}.
+
+By default, STL classes and algorithms use the @code{<} and @code{==}
+operators to compare objects, which are unsuitable for expressions, but GiNaC
+provides two functors that can be supplied as proper binary comparison
+predicates to the STL:
+
+@example
+class ex_is_less : public std::binary_function<ex, ex, bool> @{
+public:
+ bool operator()(const ex &lh, const ex &rh) const;
+@};
+
+class ex_is_equal : public std::binary_function<ex, ex, bool> @{
+public:
+ bool operator()(const ex &lh, const ex &rh) const;
+@};
+@end example
+
+For example, to define a @code{map} that maps expressions to strings you
+have to use
+
+@example
+std::map<ex, std::string, ex_is_less> myMap;
+@end example
+
+Omitting the @code{ex_is_less} template parameter will introduce spurious
+bugs because the map operates improperly.
+
+Other examples for the use of the functors:
+
+@example
+std::vector<ex> v;
+// fill vector
+...
+
+// sort vector
+std::sort(v.begin(), v.end(), ex_is_less());
+
+// count the number of expressions equal to '1'
+unsigned num_ones = std::count_if(v.begin(), v.end(),
+ std::bind2nd(ex_is_equal(), 1));
+@end example
+
+The implementation of @code{ex_is_less} uses the member function
+
+@example
+int ex::compare(const ex & other) const;
+@end example
+
+which returns @math{0} if @code{*this} and @code{other} are equal, @math{-1}
+if @code{*this} sorts before @code{other}, and @math{1} if @code{*this} sorts
+after @code{other}.
-@node Substituting Expressions, Pattern Matching and Advanced Substitutions, Information About Expressions, Methods and Functions
+@node Numerical Evaluation, Substituting Expressions, Information About Expressions, Methods and Functions
+@c node-name, next, previous, up
+@section Numerical Evaluation
+@cindex @code{evalf()}
+
+GiNaC keeps algebraic expressions, numbers and constants in their exact form.
+To evaluate them using floating-point arithmetic you need to call
+
+@example
+ex ex::evalf(int level = 0) const;
+@end example
+
+@cindex @code{Digits}
+The accuracy of the evaluation is controlled by the global object @code{Digits}
+which can be assigned an integer value. The default value of @code{Digits}
+is 17. @xref{Numbers}, for more information and examples.
+
+To evaluate an expression to a @code{double} floating-point number you can
+call @code{evalf()} followed by @code{numeric::to_double()}, like this:
+
+@example
+@{
+ // Approximate sin(x/Pi)
+ symbol x("x");
+ ex e = series(sin(x/Pi), x == 0, 6);
+
+ // Evaluate numerically at x=0.1
+ ex f = evalf(e.subs(x == 0.1));
+
+ // ex_to<numeric> is an unsafe cast, so check the type first
+ if (is_a<numeric>(f)) @{
+ double d = ex_to<numeric>(f).to_double();
+ cout << d << endl;
+ // -> 0.0318256
+ @} else
+ // error
+@}
+@end example
+
+
+@node Substituting Expressions, Pattern Matching and Advanced Substitutions, Numerical Evaluation, Methods and Functions
@c node-name, next, previous, up
@section Substituting expressions
@cindex @code{subs()}
@example
ex ex::subs(const ex & e, unsigned options = 0);
+ex ex::subs(const exmap & m, unsigned options = 0);
ex ex::subs(const lst & syms, const lst & repls, unsigned options = 0);
@end example
If you specify multiple substitutions, they are performed in parallel, so e.g.
@code{subs(lst(x == y, y == x))} exchanges @samp{x} and @samp{y}.
-The second form of @code{subs()} takes two lists, one for the objects to be
+The second form of @code{subs()} takes an @code{exmap} object which is a
+pair associative container that maps expressions to expressions (currently
+implemented as a @code{std::map}). This is the most efficient one of the
+three @code{subs()} forms and should be used when the number of objects to
+be substituted is large or unknown.
+
+Using this form, the second example from above would look like this:
+
+@example
+@{
+ symbol x("x"), y("y");
+ ex e2 = x*y + x;
+
+ exmap m;
+ m[x] = -2;
+ m[y] = 4;
+ cout << "e2(-2, 4) = " << e2.subs(m) << endl;
+@}
+@end example
+
+The third form of @code{subs()} takes two lists, one for the objects to be
replaced and one for the expressions to be substituted (both lists must
contain the same number of elements). Using this form, you would write
-@code{subs(lst(x, y), lst(y, x))} to exchange @samp{x} and @samp{y}.
+
+@example
+@{
+ symbol x("x"), y("y");
+ ex e2 = x*y + x;
+
+ cout << "e2(-2, 4) = " << e2.subs(lst(x, y), lst(-2, 4)) << endl;
+@}
+@end example
The optional last argument to @code{subs()} is a combination of
@code{subs_options} flags. There are two options available:
-@code{subs_options::subs_no_pattern} disables pattern matching, which makes
+@code{subs_options::no_pattern} disables pattern matching, which makes
large @code{subs()} operations significantly faster if you are not using
-patterns. The second option, @code{subs_options::subs_algebraic} enables
+patterns. The second option, @code{subs_options::algebraic} enables
algebraic substitutions in products and powers.
@ref{Pattern Matching and Advanced Substitutions}, for more information
about patterns and algebraic substitutions.
@end example
@subsection Algebraic substitutions
-Supplying the @code{subs_options::subs_algebraic} option to @code{subs()}
+Supplying the @code{subs_options::algebraic} option to @code{subs()}
enables smarter, algebraic substitutions in products and powers. If you want
to substitute some factors of a product, you only need to list these factors
in your pattern. Furthermore, if an (integer) power of some expression occurs
@example
cout << (a*a*a*a+b*b*b*b+pow(x+y,4)).subs(wild()*wild()==pow(wild(),3),
- subs_options::subs_algebraic) << endl;
+ subs_options::algebraic) << endl;
// --> (y+x)^6+b^6+a^6
-cout << ((a+b+c)*(a+b+c)).subs(a+b==x,subs_options::subs_algebraic) << endl;
+cout << ((a+b+c)*(a+b+c)).subs(a+b==x,subs_options::algebraic) << endl;
// --> (c+b+a)^2
// Powers and products are smart, but addition is just the same.
-cout << ((a+b+c)*(a+b+c)).subs(a+b+wild()==x+wild(), subs_options::subs_algebraic)
+cout << ((a+b+c)*(a+b+c)).subs(a+b+wild()==x+wild(), subs_options::algebraic)
<< endl;
// --> (x+c)^2
// As I said: addition is just the same.
-cout << (pow(a,5)*pow(b,7)+2*b).subs(b*b*a==x,subs_options::subs_algebraic) << endl;
+cout << (pow(a,5)*pow(b,7)+2*b).subs(b*b*a==x,subs_options::algebraic) << endl;
// --> x^3*b*a^2+2*b
-cout << (pow(a,-5)*pow(b,-7)+2*b).subs(1/(b*b*a)==x,subs_options::subs_algebraic)
+cout << (pow(a,-5)*pow(b,-7)+2*b).subs(1/(b*b*a)==x,subs_options::algebraic)
<< endl;
// --> 2*b+x^3*b^(-1)*a^(-2)
-cout << (4*x*x*x-2*x*x+5*x-1).subs(x==a,subs_options::subs_algebraic) << endl;
+cout << (4*x*x*x-2*x*x+5*x-1).subs(x==a,subs_options::algebraic) << endl;
// --> -1-2*a^2+4*a^3+5*a
cout << (4*x*x*x-2*x*x+5*x-1).subs(pow(x,wild())==pow(a,wild()),
- subs_options::subs_algebraic) << endl;
+ subs_options::algebraic) << endl;
// --> -1+5*x+4*x^3-2*x^2
// You should not really need this kind of patterns very often now.
// But perhaps this it's-not-a-bug-it's-a-feature (c/sh)ould still change.
cout << ex(sin(1+sin(x))).subs(sin(wild())==cos(wild()),
- subs_options::subs_algebraic) << endl;
+ subs_options::algebraic) << endl;
// --> cos(1+cos(x))
cout << expand((a*sin(x+y)*sin(x+y)+a*cos(x+y)*cos(x+y)+b)
.subs((pow(cos(wild()),2)==1-pow(sin(wild()),2)),
- subs_options::subs_algebraic)) << endl;
+ subs_options::algebraic)) << endl;
// --> b+a
@end example
@}
@end example
+Alternatively, you could use pre- or postorder iterators for the tree
+traversal:
+
+@example
+lst gather_indices(const ex & e)
+@{
+ gather_indices_visitor v;
+ for (const_preorder_iterator i = e.preorder_begin();
+ i != e.preorder_end(); ++i) @{
+ i->accept(v);
+ @}
+ return v.get_result();
+@}
+@end example
+
@node Polynomial Arithmetic, Rational Expressions, Visitors and Tree Traversal, Methods and Functions
@c node-name, next, previous, up
may be called. In our example above, this corresponds to @math{4*x*y +
x*z + 20*y^2 + 21*y*z + 4*z^2}. Again, since the canonical form in
-GiNaC is not easily guessable you should be prepared to see different
+GiNaC is not easy to guess you should be prepared to see different
orderings of terms in such sums!
Another useful representation of multivariate polynomials is as a
@end example
which also work reliably on non-expanded input polynomials (they even work
-on rational functions, returning the asymptotic degree). To extract
-a coefficient with a certain power from an expanded polynomial you use
+on rational functions, returning the asymptotic degree). By definition, the
+degree of zero is zero. To extract a coefficient with a certain power from
+an expanded polynomial you use
@example
ex ex::coeff(const ex & s, int n);
@example
@{
- symbol a("a"), b("b"), c("c");
+ symbol a("a"), b("b"), c("c"), x("x");
idx i(symbol("i"), 3);
ex e = pow(sin(x) - cos(x), 4);
The two functions
@example
-ex quo(const ex & a, const ex & b, const symbol & x);
-ex rem(const ex & a, const ex & b, const symbol & x);
+ex quo(const ex & a, const ex & b, const ex & x);
+ex rem(const ex & a, const ex & b, const ex & x);
@end example
compute the quotient and remainder of univariate polynomials in the variable
The additional function
@example
-ex prem(const ex & a, const ex & b, const symbol & x);
+ex prem(const ex & a, const ex & b, const ex & x);
@end example
computes the pseudo-remainder of @samp{a} and @samp{b} which satisfies
The methods
@example
-ex ex::unit(const symbol & x);
-ex ex::content(const symbol & x);
-ex ex::primpart(const symbol & x);
+ex ex::unit(const ex & x);
+ex ex::content(const ex & x);
+ex ex::primpart(const ex & x);
@end example
return the unit part, content part, and primitive polynomial of a multivariate
above. You do this by calling
@example
-ex ex::to_polynomial(lst &l);
+ex ex::to_polynomial(exmap & m);
+ex ex::to_polynomial(lst & l);
@end example
or
@example
-ex ex::to_rational(lst &l);
+ex ex::to_rational(exmap & m);
+ex ex::to_rational(lst & l);
@end example
-on the expression to be converted. The supplied @code{lst} will be filled
-with the generated temporary symbols and their replacement expressions in
-a format that can be used directly for the @code{subs()} method. It can also
-already contain a list of replacements from an earlier application of
-@code{.to_polynomial()} or @code{.to_rational()}, so it's possible to use
-it on multiple expressions and get consistent results.
+on the expression to be converted. The supplied @code{exmap} or @code{lst}
+will be filled with the generated temporary symbols and their replacement
+expressions in a format that can be used directly for the @code{subs()}
+method. It can also already contain a list of replacements from an earlier
+application of @code{.to_polynomial()} or @code{.to_rational()}, so it's
+possible to use it on multiple expressions and get consistent results.
-The difference betwerrn @code{.to_polynomial()} and @code{.to_rational()}
+The difference between @code{.to_polynomial()} and @code{.to_rational()}
is probably best illustrated with an example:
@example
ex a = pow(sin(x), 2) - pow(cos(x), 2);
ex b = sin(x) + cos(x);
ex q;
- lst l;
- divide(a.to_polynomial(l), b.to_polynomial(l), q);
- cout << q.subs(l) << endl;
+ exmap m;
+ divide(a.to_polynomial(m), b.to_polynomial(m), q);
+ cout << q.subs(m) << endl;
@}
@end example
@}
@end example
-
-@node Built-in Functions, Solving Linear Systems of Equations, Symmetrization, Methods and Functions
+@node Built-in Functions, Multiple polylogarithms, Symmetrization, Methods and Functions
@c node-name, next, previous, up
@section Predefined mathematical functions
+@c
+@subsection Overview
GiNaC contains the following predefined mathematical functions:
@cindex @code{abs()}
@item @code{csgn(x)}
@tab complex sign
+@cindex @code{conjugate()}
+@item @code{conjugate(x)}
+@tab complex conjugation
@cindex @code{csgn()}
@item @code{sqrt(x)}
@tab square root (not a GiNaC function, rather an alias for @code{pow(x, numeric(1, 2))})
@tab natural logarithm
@cindex @code{log()}
@item @code{Li2(x)}
-@tab Dilogarithm
+@tab dilogarithm
@cindex @code{Li2()}
-@item @code{zeta(x)}
-@tab Riemann's zeta function
+@item @code{Li(m, x)}
+@tab classical polylogarithm as well as multiple polylogarithm
+@cindex @code{Li()}
+@item @code{S(n, p, x)}
+@tab Nielsen's generalized polylogarithm
+@cindex @code{S()}
+@item @code{H(m, x)}
+@tab harmonic polylogarithm
+@cindex @code{H()}
+@item @code{zeta(m)}
+@tab Riemann's zeta function as well as multiple zeta value
@cindex @code{zeta()}
-@item @code{zeta(n, x)}
+@item @code{zeta(m, s)}
+@tab alternating Euler sum
+@cindex @code{zeta()}
+@item @code{zetaderiv(n, x)}
@tab derivatives of Riemann's zeta function
@item @code{tgamma(x)}
-@tab Gamma function
+@tab gamma function
@cindex @code{tgamma()}
-@cindex Gamma function
+@cindex gamma function
@item @code{lgamma(x)}
-@tab logarithm of Gamma function
+@tab logarithm of gamma function
@cindex @code{lgamma()}
@item @code{beta(x, y)}
-@tab Beta function (@code{tgamma(x)*tgamma(y)/tgamma(x+y)})
+@tab beta function (@code{tgamma(x)*tgamma(y)/tgamma(x+y)})
@cindex @code{beta()}
@item @code{psi(x)}
@tab psi (digamma) function
@item @code{psi(n, x)}
@tab derivatives of psi function (polygamma functions)
@item @code{factorial(n)}
-@tab factorial function
+@tab factorial function @math{n!}
@cindex @code{factorial()}
-@item @code{binomial(n, m)}
+@item @code{binomial(n, k)}
@tab binomial coefficients
@cindex @code{binomial()}
@item @code{Order(x)}
standard incorporate these functions in the complex domain in a manner
compatible with C99.
+@node Multiple polylogarithms, Complex Conjugation, Built-in Functions, Methods and Functions
+@c node-name, next, previous, up
+@subsection Multiple polylogarithms
+
+@cindex polylogarithm
+@cindex Nielsen's generalized polylogarithm
+@cindex harmonic polylogarithm
+@cindex multiple zeta value
+@cindex alternating Euler sum
+@cindex multiple polylogarithm
+
+The multiple polylogarithm is the most generic member of a family of functions,
+to which others like the harmonic polylogarithm, Nielsen's generalized
+polylogarithm and the multiple zeta value belong.
+Everyone of these functions can also be written as a multiple polylogarithm with specific
+parameters. This whole family of functions is therefore often referred to simply as
+multiple polylogarithms, containing @code{Li}, @code{H}, @code{S} and @code{zeta}.
+
+To facilitate the discussion of these functions we distinguish between indices and
+arguments as parameters. In the table above indices are printed as @code{m}, @code{s},
+@code{n} or @code{p}, whereas arguments are printed as @code{x}.
+
+To define a @code{Li}, @code{H} or @code{zeta} with a depth greater than one, you have to
+pass a GiNaC @code{lst} for the indices @code{m} and @code{s}, and in the case of @code{Li}
+for the argument @code{x} as well.
+Note that @code{Li} and @code{zeta} are polymorphic in this respect. They can stand in for
+the classical polylogarithm and Riemann's zeta function (if depth is one), as well as for
+the multiple polylogarithm and the multiple zeta value, respectively. Note also, that
+GiNaC doesn't check whether the @code{lst}s for two parameters do have the same length.
+It is up to the user to ensure this, otherwise evaluating will result in undefined behavior.
+
+The functions print in LaTeX format as
+@tex
+${\rm Li\;\!}_{m_1,m_2,\ldots,m_k}(x_1,x_2,\ldots,x_k)$,
+@end tex
+@tex
+${\rm S}_{n,p}(x)$,
+@end tex
+@tex
+${\rm H\;\!}_{m_1,m_2,\ldots,m_k}(x)$ and
+@end tex
+@tex
+$\zeta(m_1,m_2,\ldots,m_k)$.
+@end tex
+If @code{zeta} is an alternating zeta sum, i.e. @code{zeta(m,s)}, the indices with negative sign
+are printed with a line above, e.g.
+@tex
+$\zeta(5,\overline{2})$.
+@end tex
+The order of indices and arguments in the GiNaC @code{lst}s and in the output is the same.
+
+Definitions and analytical as well as numerical properties of multiple polylogarithms
+are too numerous to be covered here. Instead, the user is referred to the publications listed at the
+end of this section. The implementation in GiNaC adheres to the definitions and conventions therein,
+except for a few differences which will be explicitly stated in the following.
+
+One difference is about the order of the indices and arguments. For GiNaC we adopt the convention
+that the indices and arguments are understood to be in the same order as in which they appear in
+the series representation. This means
+@tex
+${\rm Li\;\!}_{m_1,m_2,m_3}(x,1,1) = {\rm H\;\!}_{m_1,m_2,m_3}(x)$ and
+@end tex
+@tex
+${\rm Li\;\!}_{2,1}(1,1) = \zeta(2,1) = \zeta(3)$, but
+@end tex
+@tex
+$\zeta(1,2)$ evaluates to infinity.
+@end tex
+So in comparison to the referenced publications the order of indices and arguments for @code{Li}
+is reversed.
+
+The functions only evaluate if the indices are integers greater than zero, except for the indices
+@code{s} in @code{zeta} and @code{m} in @code{H}. Since @code{s} will be interpreted as the sequence
+of signs for the corresponding indices @code{m}, it must contain 1 or -1, e.g.
+@code{zeta(lst(3,4), lst(-1,1))} means
+@tex
+$\zeta(\overline{3},4)$.
+@end tex
+The definition of @code{H} allows indices to be 0, 1 or -1 (in expanded notation) or equally to
+be any integer (in compact notation). With GiNaC expanded and compact notation can be mixed,
+e.g. @code{lst(0,0,-1,0,1,0,0)}, @code{lst(0,0,-1,2,0,0)} and @code{lst(-3,2,0,0)} are equivalent as
+indices. The anonymous evaluator @code{eval()} tries to reduce the functions, if possible, to
+the least-generic multiple polylogarithm. If all arguments are unit, it returns @code{zeta}.
+Arguments equal to zero get considered, too. Riemann's zeta function @code{zeta} (with depth one)
+evaluates also for negative integers and positive even integers. For example:
+
+@example
+> Li(@{3,1@},@{x,1@});
+S(2,2,x)
+> H(@{-3,2@},1);
+-zeta(@{3,2@},@{-1,-1@})
+> S(3,1,1);
+1/90*Pi^4
+@end example
+
+It is easy to tell for a given function into which other function it can be rewritten, may
+it be a less-generic or a more-generic one, except for harmonic polylogarithms @code{H}
+with negative indices or trailing zeros (the example above gives a hint). Signs can
+quickly be messed up, for example. Therefore GiNaC offers a C++ function
+@code{convert_H_to_Li()} to deal with the upgrade of a @code{H} to a multiple polylogarithm
+@code{Li} (@code{eval()} already cares for the possible downgrade):
+
+@example
+> convert_H_to_Li(@{0,-2,-1,3@},x);
+Li(@{3,1,3@},@{-x,1,-1@})
+> convert_H_to_Li(@{2,-1,0@},x);
+-Li(@{2,1@},@{x,-1@})*log(x)+2*Li(@{3,1@},@{x,-1@})+Li(@{2,2@},@{x,-1@})
+@end example
+
+Every function apart from the multiple polylogarithm @code{Li} can be numerically evaluated for
+arbitrary real or complex arguments. @code{Li} only evaluates if for all arguments
+@tex
+$x_i$ the condition
+@end tex
+@tex
+$x_1x_2\cdots x_i < 1$ holds.
+@end tex
+
+@example
+> Digits=100;
+100
+> evalf(zeta(@{3,1,3,1@}));
+0.005229569563530960100930652283899231589890420784634635522547448972148869544...
+@end example
+
+Note that the convention for arguments on the branch cut in GiNaC as stated above is
+different from the one Remiddi and Vermaseren have chosen for the harmonic polylogarithm.
+
+If a function evaluates to infinity, no exceptions are raised, but the function is returned
+unevaluated, e.g.
+@tex
+$\zeta(1)$.
+@end tex
+In long expressions this helps a lot with debugging, because you can easily spot
+the divergencies. But on the other hand, you have to make sure for yourself, that no illegal
+cancellations of divergencies happen.
+
+Useful publications:
+
+@cite{Nested Sums, Expansion of Transcendental Functions and Multi-Scale Multi-Loop Integrals},
+S.Moch, P.Uwer, S.Weinzierl, hep-ph/0110083
+
+@cite{Harmonic Polylogarithms},
+E.Remiddi, J.A.M.Vermaseren, Int.J.Mod.Phys. A15 (2000), pp. 725-754
-@node Solving Linear Systems of Equations, Input/Output, Built-in Functions, Methods and Functions
+@cite{Special Values of Multiple Polylogarithms},
+J.Borwein, D.Bradley, D.Broadhurst, P.Lisonek, Trans.Amer.Math.Soc. 353/3 (2001), pp. 907-941
+
+@node Complex Conjugation, Solving Linear Systems of Equations, Multiple polylogarithms, Methods and Functions
+@c node-name, next, previous, up
+@section Complex Conjugation
+@c
+@cindex @code{conjugate()}
+
+The method
+
+@example
+ex ex::conjugate();
+@end example
+
+returns the complex conjugate of the expression. For all built-in functions and objects the
+conjugation gives the expected results:
+
+@example
+@{
+ varidx a(symbol("a"), 4), b(symbol("b"), 4);
+ symbol x("x");
+ realsymbol y("y");
+
+ cout << (3*I*x*y + sin(2*Pi*I*y)).conjugate() << endl;
+ // -> -3*I*conjugate(x)*y+sin(-2*I*Pi*y)
+ cout << (dirac_gamma(a)*dirac_gamma(b)*dirac_gamma5()).conjugate() << endl;
+ // -> -gamma5*gamma~b*gamma~a
+@}
+@end example
+
+For symbols in the complex domain the conjugation can not be evaluated and the GiNaC function
+@code{conjugate} is returned. GiNaC functions conjugate by applying the conjugation to their
+arguments. This is the default strategy. If you want to define your own functions and want to
+change this behavior, you have to supply a specialized conjugation method for your function
+(see @ref{Symbolic functions} and the GiNaC source-code for @code{abs} as an example).
+
+@node Solving Linear Systems of Equations, Input/Output, Complex Conjugation, Methods and Functions
@c node-name, next, previous, up
@section Solving Linear Systems of Equations
@cindex @code{lsolve()}
@example
@{
symbol a("a"), b("b"), x("x"), y("y");
- lst eqns;
- eqns.append(a*x+b*y==3).append(x-y==b);
- lst vars;
- vars.append(x).append(y);
+ lst eqns, vars;
+ eqns = a*x+b*y==3, x-y==b;
+ vars = x, y;
cout << lsolve(eqns, vars) << endl;
- // -> @{x==(3+b^2)/(b+a),y==(3-b*a)/(b+a)@}
+ // -> @{x==(3+b^2)/(b+a),y==(3-b*a)/(b+a)@}
@end example
When the linear equations @code{eqns} are underdetermined, the solution
if (is_a<function>(e))
cout << ex_to<function>(e).get_name();
else
- cout << e.bp->class_name();
+ cout << ex_to<basic>(e).class_name();
cout << "(";
size_t n = e.nops();
if (n)
@example
// ...
- lst syms(x, y);
+ lst syms;
+ syms = x, y;
ex ex1 = a2.unarchive_ex(syms, "foo");
ex ex2 = a2.unarchive_ex(syms, "the second one");
@chapter Extending GiNaC
By reading so far you should have gotten a fairly good understanding of
-GiNaC's design-patterns. From here on you should start reading the
+GiNaC's design patterns. From here on you should start reading the
sources. All we can do now is issue some recommendations how to tackle
GiNaC's many loose ends in order to fulfill everybody's dreams. If you
develop some useful extension please don't hesitate to contact the GiNaC
@menu
* What does not belong into GiNaC:: What to avoid.
* Symbolic functions:: Implementing symbolic functions.
+* Printing:: Adding new output formats.
* Structures:: Defining new algebraic classes (the easy way).
* Adding classes:: Defining new algebraic classes (the hard way).
@end menu
provided by CLN are much better suited.
-@node Symbolic functions, Structures, What does not belong into GiNaC, Extending GiNaC
+@node Symbolic functions, Printing, What does not belong into GiNaC, Extending GiNaC
@c node-name, next, previous, up
@section Symbolic functions
@example
DECLARE_FUNCTION_2P(myfcn)
-static ex myfcn_eval(const ex & x, const ex & y)
-@{
- return myfcn(x, y).hold();
-@}
-
-REGISTER_FUNCTION(myfcn, eval_func(myfcn_eval))
+REGISTER_FUNCTION(myfcn, dummy())
@end example
Any code that has seen the @code{DECLARE_FUNCTION} line can use @code{myfcn()}
@{
...
symbol x("x");
- ex e = 2*myfcn(42, 3*x+1) - x;
- // this calls myfcn_eval(42, 3*x+1), and inserts its return value into
- // the actual expression
+ ex e = 2*myfcn(42, 1+3*x) - x;
cout << e << endl;
// prints '2*myfcn(42,1+3*x)-x'
...
@}
@end example
-@cindex @code{hold()}
-@cindex evaluation
-The @code{eval_func()} option specifies the C++ function that implements
-the @code{eval()} method, GiNaC's anonymous evaluator. This function takes
-the same number of arguments as the associated symbolic function (two in this
-case) and returns the (possibly transformed or in some way simplified)
-symbolically evaluated function (@xref{Automatic evaluation}, for a description
-of the automatic evaluation process). If no (further) evaluation is to take
-place, the @code{eval_func()} function must return the original function
-with @code{.hold()}, to avoid a potential infinite recursion. If your
-symbolic functions produce a segmentation fault or stack overflow when
-using them in expressions, you are probably missing a @code{.hold()}
-somewhere.
+The @code{dummy()} option in the @code{REGISTER_FUNCTION} line signifies
+"no options". A function with no options specified merely acts as a kind of
+container for its arguments. It is a pure "dummy" function with no associated
+logic (which is, however, sometimes perfectly sufficient).
-There is not much you can do with the @code{myfcn} function. It merely acts
-as a kind of container for its arguments (which is, however, sometimes
-perfectly sufficient). Let's have a look at the implementation of GiNaC's
-cosine function.
+Let's now have a look at the implementation of GiNaC's cosine function for an
+example of how to make an "intelligent" function.
@subsection The cosine function
that takes one @code{ex} as an argument. This is all they need to know to use
this function in expressions.
-The implementation of the cosine function is in @file{inifcns_trans.cpp}. The
-@code{eval_func()} function looks something like this (actually, it doesn't
-look like this at all, but it should give you an idea what is going on):
+The implementation of the cosine function is in @file{inifcns_trans.cpp}. Here
+is its @code{REGISTER_FUNCTION} line:
+
+@example
+REGISTER_FUNCTION(cos, eval_func(cos_eval).
+ evalf_func(cos_evalf).
+ derivative_func(cos_deriv).
+ latex_name("\\cos"));
+@end example
+
+There are four options defined for the cosine function. One of them
+(@code{latex_name}) gives the function a proper name for LaTeX output; the
+other three indicate the C++ functions in which the "brains" of the cosine
+function are defined.
+
+@cindex @code{hold()}
+@cindex evaluation
+The @code{eval_func()} option specifies the C++ function that implements
+the @code{eval()} method, GiNaC's anonymous evaluator. This function takes
+the same number of arguments as the associated symbolic function (one in this
+case) and returns the (possibly transformed or in some way simplified)
+symbolically evaluated function (@xref{Automatic evaluation}, for a description
+of the automatic evaluation process). If no (further) evaluation is to take
+place, the @code{eval_func()} function must return the original function
+with @code{.hold()}, to avoid a potential infinite recursion. If your
+symbolic functions produce a segmentation fault or stack overflow when
+using them in expressions, you are probably missing a @code{.hold()}
+somewhere.
+
+The @code{eval_func()} function for the cosine looks something like this
+(actually, it doesn't look like this at all, but it should give you an idea
+what is going on):
@example
static ex cos_eval(const ex & x)
@{
- if (<x is a multiple of 2*Pi>)
+ if ("x is a multiple of 2*Pi")
return 1;
- else if (<x is a multiple of Pi>)
+ else if ("x is a multiple of Pi")
return -1;
- else if (<x is a multiple of Pi/2>)
+ else if ("x is a multiple of Pi/2")
return 0;
// more rules...
- else if (<x has the form 'acos(y)'>)
+ else if ("x has the form 'acos(y)'")
return y;
- else if (<x has the form 'asin(y)'>)
+ else if ("x has the form 'asin(y)'")
return sqrt(1-y^2);
// more rules...
@}
@end example
+This function is called every time the cosine is used in a symbolic expression:
+
+@example
+@{
+ ...
+ e = cos(Pi);
+ // this calls cos_eval(Pi), and inserts its return value into
+ // the actual expression
+ cout << e << endl;
+ // prints '-1'
+ ...
+@}
+@end example
+
In this way, @code{cos(4*Pi)} automatically becomes @math{1},
@code{cos(asin(a+b))} becomes @code{sqrt(1-(a+b)^2)}, etc. If no reasonable
symbolic transformation can be done, the unmodified function is returned
// Find the actual expansion point
const ex x_pt = x.subs(rel);
- if (<x_pt is not an odd multiple of Pi/2>)
+ if ("x_pt is not an odd multiple of Pi/2")
throw do_taylor(); // tell function::series() to do Taylor expansion
// On a pole, expand sin()/cos()
The @code{series()} implementation of a function @emph{must} return a
@code{pseries} object, otherwise your code will crash.
-Now that all the ingredients have been set up, the @code{REGISTER_FUNCTION}
-macro is used to tell the system how the @code{cos()} function behaves:
-
-@example
-REGISTER_FUNCTION(cos, eval_func(cos_eval).
- evalf_func(cos_evalf).
- derivative_func(cos_deriv).
- latex_name("\\cos"));
-@end example
-
-This registers the @code{cos_eval()}, @code{cos_evalf()} and
-@code{cos_deriv()} C++ functions with the @code{cos()} function, and also
-gives it a proper LaTeX name.
-
@subsection Function options
GiNaC functions understand several more options which are always
specified as @code{.option(params)}. None of them are required, but you
-need to specify at least one option to @code{REGISTER_FUNCTION()} (usually
-the @code{eval()} method).
+need to specify at least one option to @code{REGISTER_FUNCTION()}. There
+is a do-nothing option called @code{dummy()} which you can use to define
+functions without any special options.
@example
eval_func(<C++ function>)
evalf_func(<C++ function>)
derivative_func(<C++ function>)
series_func(<C++ function>)
+conjugate_func(<C++ function>)
@end example
These specify the C++ functions that implement symbolic evaluation,
specifications. GiNaC will automatically rearrange the arguments of
symmetric functions into a canonical order.
+Sometimes you may want to have finer control over how functions are
+displayed in the output. For example, the @code{abs()} function prints
+itself as @samp{abs(x)} in the default output format, but as @samp{|x|}
+in LaTeX mode, and @code{fabs(x)} in C source output. This is achieved
+with the
+
+@example
+print_func<C>(<C++ function>)
+@end example
+
+option which is explained in the next section.
+
+
+@node Printing, Structures, Symbolic functions, Extending GiNaC
+@c node-name, next, previous, up
+@section GiNaC's expression output system
+
+GiNaC allows the output of expressions in a variety of different formats
+(@pxref{Input/Output}). This section will explain how expression output
+is implemented internally, and how to define your own output formats or
+change the output format of built-in algebraic objects. You will also want
+to read this section if you plan to write your own algebraic classes or
+functions.
+
+@cindex @code{print_context} (class)
+@cindex @code{print_dflt} (class)
+@cindex @code{print_latex} (class)
+@cindex @code{print_tree} (class)
+@cindex @code{print_csrc} (class)
+All the different output formats are represented by a hierarchy of classes
+rooted in the @code{print_context} class, defined in the @file{print.h}
+header file:
+
+@table @code
+@item print_dflt
+the default output format
+@item print_latex
+output in LaTeX mathematical mode
+@item print_tree
+a dump of the internal expression structure (for debugging)
+@item print_csrc
+the base class for C source output
+@item print_csrc_float
+C source output using the @code{float} type
+@item print_csrc_double
+C source output using the @code{double} type
+@item print_csrc_cl_N
+C source output using CLN types
+@end table
+
+The @code{print_context} base class provides two public data members:
+
+@example
+class print_context
+@{
+ ...
+public:
+ std::ostream & s;
+ unsigned options;
+@};
+@end example
+
+@code{s} is a reference to the stream to output to, while @code{options}
+holds flags and modifiers. Currently, there is only one flag defined:
+@code{print_options::print_index_dimensions} instructs the @code{idx} class
+to print the index dimension which is normally hidden.
+
+When you write something like @code{std::cout << e}, where @code{e} is
+an object of class @code{ex}, GiNaC will construct an appropriate
+@code{print_context} object (of a class depending on the selected output
+format), fill in the @code{s} and @code{options} members, and call
+
+@cindex @code{print()}
+@example
+void ex::print(const print_context & c, unsigned level = 0) const;
+@end example
+
+which in turn forwards the call to the @code{print()} method of the
+top-level algebraic object contained in the expression.
+
+Unlike other methods, GiNaC classes don't usually override their
+@code{print()} method to implement expression output. Instead, the default
+implementation @code{basic::print(c, level)} performs a run-time double
+dispatch to a function selected by the dynamic type of the object and the
+passed @code{print_context}. To this end, GiNaC maintains a separate method
+table for each class, similar to the virtual function table used for ordinary
+(single) virtual function dispatch.
+
+The method table contains one slot for each possible @code{print_context}
+type, indexed by the (internally assigned) serial number of the type. Slots
+may be empty, in which case GiNaC will retry the method lookup with the
+@code{print_context} object's parent class, possibly repeating the process
+until it reaches the @code{print_context} base class. If there's still no
+method defined, the method table of the algebraic object's parent class
+is consulted, and so on, until a matching method is found (eventually it
+will reach the combination @code{basic/print_context}, which prints the
+object's class name enclosed in square brackets).
+
+You can think of the print methods of all the different classes and output
+formats as being arranged in a two-dimensional matrix with one axis listing
+the algebraic classes and the other axis listing the @code{print_context}
+classes.
+
+Subclasses of @code{basic} can, of course, also overload @code{basic::print()}
+to implement printing, but then they won't get any of the benefits of the
+double dispatch mechanism (such as the ability for derived classes to
+inherit only certain print methods from its parent, or the replacement of
+methods at run-time).
+
+@subsection Print methods for classes
+
+The method table for a class is set up either in the definition of the class,
+by passing the appropriate @code{print_func<C>()} option to
+@code{GINAC_IMPLEMENT_REGISTERED_CLASS_OPT()} (@xref{Adding classes}, for
+an example), or at run-time using @code{set_print_func<T, C>()}. The latter
+can also be used to override existing methods dynamically.
+
+The argument to @code{print_func<C>()} and @code{set_print_func<T, C>()} can
+be a member function of the class (or one of its parent classes), a static
+member function, or an ordinary (global) C++ function. The @code{C} template
+parameter specifies the appropriate @code{print_context} type for which the
+method should be invoked, while, in the case of @code{set_print_func<>()}, the
+@code{T} parameter specifies the algebraic class (for @code{print_func<>()},
+the class is the one being implemented by
+@code{GINAC_IMPLEMENT_REGISTERED_CLASS_OPT}).
+
+For print methods that are member functions, their first argument must be of
+a type convertible to a @code{const C &}, and the second argument must be an
+@code{unsigned}.
+
+For static members and global functions, the first argument must be of a type
+convertible to a @code{const T &}, the second argument must be of a type
+convertible to a @code{const C &}, and the third argument must be an
+@code{unsigned}. A global function will, of course, not have access to
+private and protected members of @code{T}.
+
+The @code{unsigned} argument of the print methods (and of @code{ex::print()}
+and @code{basic::print()}) is used for proper parenthesizing of the output
+(and by @code{print_tree} for proper indentation). It can be used for similar
+purposes if you write your own output formats.
+
+The explanations given above may seem complicated, but in practice it's
+really simple, as shown in the following example. Suppose that we want to
+display exponents in LaTeX output not as superscripts but with little
+upwards-pointing arrows. This can be achieved in the following way:
+
+@example
+void my_print_power_as_latex(const power & p,
+ const print_latex & c,
+ unsigned level)
+@{
+ // get the precedence of the 'power' class
+ unsigned power_prec = p.precedence();
+
+ // if the parent operator has the same or a higher precedence
+ // we need parentheses around the power
+ if (level >= power_prec)
+ c.s << '(';
+
+ // print the basis and exponent, each enclosed in braces, and
+ // separated by an uparrow
+ c.s << '@{';
+ p.op(0).print(c, power_prec);
+ c.s << "@}\\uparrow@{";
+ p.op(1).print(c, power_prec);
+ c.s << '@}';
+
+ // don't forget the closing parenthesis
+ if (level >= power_prec)
+ c.s << ')';
+@}
+
+int main()
+@{
+ // a sample expression
+ symbol x("x"), y("y");
+ ex e = -3*pow(x, 3)*pow(y, -2) + pow(x+y, 2) - 1;
+
+ // switch to LaTeX mode
+ cout << latex;
+
+ // this prints "-1+@{(y+x)@}^@{2@}-3 \frac@{x^@{3@}@}@{y^@{2@}@}"
+ cout << e << endl;
+
+ // now we replace the method for the LaTeX output of powers with
+ // our own one
+ set_print_func<power, print_latex>(my_print_power_as_latex);
+
+ // this prints "-1+@{@{(y+x)@}@}\uparrow@{2@}-3 \frac@{@{x@}\uparrow@{3@}@}@{@{y@}\uparrow@{2@}@}"
+ cout << e << endl;
+@}
+@end example
+
+Some notes:
+
+@itemize
+
+@item
+The first argument of @code{my_print_power_as_latex} could also have been
+a @code{const basic &}, the second one a @code{const print_context &}.
+
+@item
+The above code depends on @code{mul} objects converting their operands to
+@code{power} objects for the purpose of printing.
+
+@item
+The output of products including negative powers as fractions is also
+controlled by the @code{mul} class.
+
+@item
+The @code{power/print_latex} method provided by GiNaC prints square roots
+using @code{\sqrt}, but the above code doesn't.
+
+@end itemize
+
+It's not possible to restore a method table entry to its previous or default
+value. Once you have called @code{set_print_func()}, you can only override
+it with another call to @code{set_print_func()}, but you can't easily go back
+to the default behavior again (you can, of course, dig around in the GiNaC
+sources, find the method that is installed at startup
+(@code{power::do_print_latex} in this case), and @code{set_print_func} that
+one; that is, after you circumvent the C++ member access control@dots{}).
+
+@subsection Print methods for functions
+
+Symbolic functions employ a print method dispatch mechanism similar to the
+one used for classes. The methods are specified with @code{print_func<C>()}
+function options. If you don't specify any special print methods, the function
+will be printed with its name (or LaTeX name, if supplied), followed by a
+comma-separated list of arguments enclosed in parentheses.
-@node Structures, Adding classes, Symbolic functions, Extending GiNaC
+For example, this is what GiNaC's @samp{abs()} function is defined like:
+
+@example
+static ex abs_eval(const ex & arg) @{ ... @}
+static ex abs_evalf(const ex & arg) @{ ... @}
+
+static void abs_print_latex(const ex & arg, const print_context & c)
+@{
+ c.s << "@{|"; arg.print(c); c.s << "|@}";
+@}
+
+static void abs_print_csrc_float(const ex & arg, const print_context & c)
+@{
+ c.s << "fabs("; arg.print(c); c.s << ")";
+@}
+
+REGISTER_FUNCTION(abs, eval_func(abs_eval).
+ evalf_func(abs_evalf).
+ print_func<print_latex>(abs_print_latex).
+ print_func<print_csrc_float>(abs_print_csrc_float).
+ print_func<print_csrc_double>(abs_print_csrc_float));
+@end example
+
+This will display @samp{abs(x)} as @samp{|x|} in LaTeX mode and @code{fabs(x)}
+in non-CLN C source output, but as @code{abs(x)} in all other formats.
+
+There is currently no equivalent of @code{set_print_func()} for functions.
+
+@subsection Adding new output formats
+
+Creating a new output format involves subclassing @code{print_context},
+which is somewhat similar to adding a new algebraic class
+(@pxref{Adding classes}). There is a macro @code{GINAC_DECLARE_PRINT_CONTEXT}
+that needs to go into the class definition, and a corresponding macro
+@code{GINAC_IMPLEMENT_PRINT_CONTEXT} that has to appear at global scope.
+Every @code{print_context} class needs to provide a default constructor
+and a constructor from an @code{std::ostream} and an @code{unsigned}
+options value.
+
+Here is an example for a user-defined @code{print_context} class:
+
+@example
+class print_myformat : public print_dflt
+@{
+ GINAC_DECLARE_PRINT_CONTEXT(print_myformat, print_dflt)
+public:
+ print_myformat(std::ostream & os, unsigned opt = 0)
+ : print_dflt(os, opt) @{@}
+@};
+
+print_myformat::print_myformat() : print_dflt(std::cout) @{@}
+
+GINAC_IMPLEMENT_PRINT_CONTEXT(print_myformat, print_dflt)
+@end example
+
+That's all there is to it. None of the actual expression output logic is
+implemented in this class. It merely serves as a selector for choosing
+a particular format. The algorithms for printing expressions in the new
+format are implemented as print methods, as described above.
+
+@code{print_myformat} is a subclass of @code{print_dflt}, so it behaves
+exactly like GiNaC's default output format:
+
+@example
+@{
+ symbol x("x");
+ ex e = pow(x, 2) + 1;
+
+ // this prints "1+x^2"
+ cout << e << endl;
+
+ // this also prints "1+x^2"
+ e.print(print_myformat()); cout << endl;
+
+ ...
+@}
+@end example
+
+To fill @code{print_myformat} with life, we need to supply appropriate
+print methods with @code{set_print_func()}, like this:
+
+@example
+// This prints powers with '**' instead of '^'. See the LaTeX output
+// example above for explanations.
+void print_power_as_myformat(const power & p,
+ const print_myformat & c,
+ unsigned level)
+@{
+ unsigned power_prec = p.precedence();
+ if (level >= power_prec)
+ c.s << '(';
+ p.op(0).print(c, power_prec);
+ c.s << "**";
+ p.op(1).print(c, power_prec);
+ if (level >= power_prec)
+ c.s << ')';
+@}
+
+@{
+ ...
+ // install a new print method for power objects
+ set_print_func<power, print_myformat>(print_power_as_myformat);
+
+ // now this prints "1+x**2"
+ e.print(print_myformat()); cout << endl;
+
+ // but the default format is still "1+x^2"
+ cout << e << endl;
+@}
+@end example
+
+
+@node Structures, Adding classes, Printing, Extending GiNaC
@c node-name, next, previous, up
@section Structures
@end example
By default, any structure types you define will be printed as
-@samp{[structure object]}. To override this, you can specialize the
-template's @code{print()} member function. The member functions of
-GiNaC classes are described in more detail in the next section, but
-it shouldn't be hard to figure out what's going on here:
+@samp{[structure object]}. To override this you can either specialize the
+template's @code{print()} member function, or specify print methods with
+@code{set_print_func<>()}, as described in @ref{Printing}. Unfortunately,
+it's not possible to supply class options like @code{print_func<>()} to
+structures, so for a self-contained structure type you need to resort to
+overriding the @code{print()} function, which is also what we will do here.
+
+The member functions of GiNaC classes are described in more detail in the
+next section, but it shouldn't be hard to figure out what's going on here:
@example
void sprod::print(const print_context & c, unsigned level) const
The disadvantage of this proprietary RTTI implementation is that there's
a little more to do when implementing new classes (C++'s RTTI works more
-or less automatic) but don't worry, most of the work is simplified by
+or less automatically) but don't worry, most of the work is simplified by
macros.
@subsection A minimalistic example
@end example
The @code{GINAC_DECLARE_REGISTERED_CLASS} and @code{GINAC_IMPLEMENT_REGISTERED_CLASS}
-macros are defined in @file{registrar.h}. They take the name of the class
+macros are defined in @file{registrar.h}. They take the name of the class
and its direct superclass as arguments and insert all required declarations
for the RTTI system. The @code{GINAC_DECLARE_REGISTERED_CLASS} should be
the first line after the opening brace of the class definition. The
@code{GINAC_DECLARE_REGISTERED_CLASS} contains, among other things the
declarations of the default constructor and a couple of other functions that
-are required. It also defines a type @code{inherited} which refers to the
+are required. It also defines a type @code{inherited} which refers to the
superclass so you don't have to modify your code every time you shuffle around
-the class hierarchy. @code{GINAC_IMPLEMENT_REGISTERED_CLASS} registers the
-class with the GiNaC RTTI.
+the class hierarchy. @code{GINAC_IMPLEMENT_REGISTERED_CLASS} registers the
+class with the GiNaC RTTI (there is also a
+@code{GINAC_IMPLEMENT_REGISTERED_CLASS_OPT} which allows specifying additional
+options for the class, and which we will be using instead in a few minutes).
Now there are seven member functions we have to implement to get a working
class:
@end example
Hm, not exactly what we expect, but of course the @code{mystring} class
-doesn't yet know how to print itself. This is done in the @code{print()}
-member function. Let's say that we wanted to print the string surrounded
-by double quotes:
+doesn't yet know how to print itself. This can be done either by implementing
+the @code{print()} member function, or, preferably, by specifying a
+@code{print_func<>()} class option. Let's say that we want to print the string
+surrounded by double quotes:
@example
class mystring : public basic
@{
...
-public:
- void print(const print_context &c, unsigned level = 0) const;
+protected:
+ void do_print(const print_context &c, unsigned level = 0) const;
...
@};
-void mystring::print(const print_context &c, unsigned level) const
+void mystring::do_print(const print_context &c, unsigned level) const
@{
// print_context::s is a reference to an ostream
c.s << '\"' << str << '\"';
@end example
The @code{level} argument is only required for container classes to
-correctly parenthesize the output. Let's try again to print the expression:
+correctly parenthesize the output.
+
+Now we need to tell GiNaC that @code{mystring} objects should use the
+@code{do_print()} member function for printing themselves. For this, we
+replace the line
+
+@example
+GINAC_IMPLEMENT_REGISTERED_CLASS(mystring, basic)
+@end example
+
+with
+
+@example
+GINAC_IMPLEMENT_REGISTERED_CLASS_OPT(mystring, basic,
+ print_func<print_context>(&mystring::do_print))
+@end example
+
+Let's try again to print the expression:
@example
cout << e << endl;
// -> "Hello, world!"
@end example
-Much better. The @code{mystring} class can be used in arbitrary expressions:
+Much better. If we wanted to have @code{mystring} objects displayed in a
+different way depending on the output format (default, LaTeX, etc.), we
+would have supplied multiple @code{print_func<>()} options with different
+template parameters (@code{print_dflt}, @code{print_latex}, etc.),
+separated by dots. This is similar to the way options are specified for
+symbolic functions. @xref{Printing}, for a more in-depth description of the
+way expression output is implemented in GiNaC.
+
+The @code{mystring} class can be used in arbitrary expressions:
@example
e += mystring("GiNaC rulez");
happens. Knowing this will enable you to write much more efficient
code. If you still have an uncertain feeling with copy-on-write
semantics, we recommend you have a look at the
-@uref{http://www.cerfnet.com/~mpcline/c++-faq-lite/, C++-FAQ lite} by
+@uref{http://www.parashift.com/c++-faq-lite/, C++-FAQ lite} by
Marshall Cline. Chapter 16 covers this issue and presents an
implementation which is pretty close to the one in GiNaC.
and the @samp{AM_PATH_GINAC} macro. The program used here is @file{simple.cpp}:
@example
+#include <iostream>
#include <ginac/ginac.h>
int main()
git://www.ginac.de / ginac.git / blobdiff