X-Git-Url: https://www.ginac.de/ginac.git//ginac.git?p=ginac.git;a=blobdiff_plain;f=ginac%2Fflags.h;h=ef921600aaa25483a58d54e846007b8c395a33e9;hp=1c9cf0847c1c7646f0c439de4b5794a5a17169d7;hb=c1285bb62f3a86454ca26260cf8b4352238a1fc5;hpb=19c8f943c15dcc0d946fb4d5fef11e487d34857a

diff --git a/ginac/flags.h b/ginac/flags.h
index 1c9cf084..ef921600 100644
--- a/ginac/flags.h
+++ b/ginac/flags.h
@@ -3,7 +3,7 @@
  *  Collection of all flags used through the GiNaC framework. */
 
 /*
- *  GiNaC Copyright (C) 1999-2000 Johannes Gutenberg University Mainz, Germany
+ *  GiNaC Copyright (C) 1999-2003 Johannes Gutenberg University Mainz, Germany
  *
  *  This program is free software; you can redistribute it and/or modify
  *  it under the terms of the GNU General Public License as published by
@@ -23,52 +23,154 @@
 #ifndef __GINAC_FLAGS_H__
 #define __GINAC_FLAGS_H__
 
-#ifndef NO_NAMESPACE_GINAC
 namespace GiNaC {
-#endif // ndef NO_NAMESPACE_GINAC
 
+/** Flags to control the behavior of expand(). */
 class expand_options {
 public:
 	enum {
-		expand_trigonometric = 0x0001
+		expand_indexed = 0x0001,      ///< expands (a+b).i to a.i+b.i
+		expand_function_args = 0x0002 ///< expands the arguments of functions
 	};
 };
 
+/** Flags to control the behavior of subs(). */
+class subs_options {
+public:
+	enum {
+		no_pattern = 0x0001,             ///< disable pattern matching
+		subs_no_pattern = 0x0001, // for backwards compatibility
+		algebraic = 0x0002,              ///< enable algebraic substitutions
+		subs_algebraic = 0x0002,  // for backwards compatibility
+        pattern_is_product = 0x0004,     ///< used internally by expairseq::subschildren()
+        pattern_is_not_product = 0x0008  ///< used internally by expairseq::subschildren()
+	};
+};
+
+/** Flags to control series expansion. */
 class series_options {
 public:
 	enum {
+		/** Suppress branch cuts in series expansion.  Branch cuts manifest
+		 *  themselves as step functions, if this option is not passed.  If
+		 *  it is passed and expansion at a point on a cut is performed, then
+		 *  the analytic continuation of the function is expanded. */
 		suppress_branchcut = 0x0001
 	};
 };
 
+/** Switch to control algorithm for determinant computation. */
 class determinant_algo {
 public:
 	enum {
+		/** Let the system choose.  A heuristics is applied for automatic
+		 *  determination of a suitable algorithm. */
 		automatic,
+		/** Gauss elimination.  If \f$m_{i,j}^{(0)}\f$ are the entries of the
+		 *  original matrix, then the matrix is transformed into triangular
+		 *  form by applying the rules
+		 *  \f[
+		 *      m_{i,j}^{(k+1)} = m_{i,j}^{(k)} - m_{i,k}^{(k)} m_{k,j}^{(k)} / m_{k,k}^{(k)}
+		 *  \f]
+		 *  The determinant is then just the product of diagonal elements.
+		 *  Choose this algorithm only for purely numerical matrices. */
 		gauss,
+		/** Division-free elimination.  This is a modification of Gauss
+		 *  elimination where the division by the pivot element is not
+		 *  carried out.  If \f$m_{i,j}^{(0)}\f$ are the entries of the
+		 *  original matrix, then the matrix is transformed into triangular
+		 *  form by applying the rules
+		 *  \f[
+		 *      m_{i,j}^{(k+1)} = m_{i,j}^{(k)} m_{k,k}^{(k)} - m_{i,k}^{(k)} m_{k,j}^{(k)}
+		 *  \f]
+		 *  The determinant can later be computed by inspecting the diagonal
+		 *  elements only.  This algorithm is only there for the purpose of
+		 *  cross-checks.  It is never fast. */
 		divfree,
+		/** Laplace elimination.  This is plain recursive elimination along
+		 *  minors although multiple minors are avoided by the algorithm.
+		 *  Although the algorithm is exponential in complexity it is
+		 *  frequently the fastest one when the matrix is populated by
+		 *  complicated symbolic expressions. */
 		laplace,
+		/** Bareiss fraction-free elimination.  This is a modification of
+		 *  Gauss elimination where the division by the pivot element is
+		 *  <EM>delayed</EM> until it can be carried out without computing
+		 *  GCDs.  If \f$m_{i,j}^{(0)}\f$ are the entries of the original
+		 *  matrix, then the matrix is transformed into triangular form by
+		 *  applying the rules
+		 *  \f[
+		 *      m_{i,j}^{(k+1)} = (m_{i,j}^{(k)} m_{k,k}^{(k)} - m_{i,k}^{(k)} m_{k,j}^{(k)}) / m_{k-1,k-1}^{(k-1)}
+		 *  \f]
+		 *  (We have set \f$m_{-1,-1}^{(-1)}=1\f$ in order to avoid a case
+		 *  distinction in above formula.)  It can be shown that nothing more
+		 *  than polynomial long division is needed for carrying out the
+		 *  division.  The determinant can then be read of from the lower
+		 *  right entry.  This algorithm is rarely fast for computing
+		 *  determinants. */
 		bareiss
 	};
 };
 
+/** Switch to control algorithm for linear system solving. */
 class solve_algo {
 public:
 	enum {
+		/** Let the system choose.  A heuristics is applied for automatic
+		 *  determination of a suitable algorithm. */
 		automatic,
+		/** Gauss elimination.  If \f$m_{i,j}^{(0)}\f$ are the entries of the
+		 *  original matrix, then the matrix is transformed into triangular
+		 *  form by applying the rules
+		 *  \f[
+		 *      m_{i,j}^{(k+1)} = m_{i,j}^{(k)} - m_{i,k}^{(k)} m_{k,j}^{(k)} / m_{k,k}^{(k)}
+		 *  \f]
+		 *  This algorithm is well-suited for numerical matrices but generally
+		 *  suffers from the expensive division (and computation of GCDs) at
+		 *  each step. */
 		gauss,
+		/** Division-free elimination.  This is a modification of Gauss
+		 *  elimination where the division by the pivot element is not
+		 *  carried out.  If \f$m_{i,j}^{(0)}\f$ are the entries of the
+		 *  original matrix, then the matrix is transformed into triangular
+		 *  form by applying the rules
+		 *  \f[
+		 *      m_{i,j}^{(k+1)} = m_{i,j}^{(k)} m_{k,k}^{(k)} - m_{i,k}^{(k)} m_{k,j}^{(k)}
+		 *  \f]
+		 *  This algorithm is only there for the purpose of cross-checks.
+		 *  It suffers from exponential intermediate expression swell.  Use it
+		 *  only for small systems. */
 		divfree,
+		/** Bareiss fraction-free elimination.  This is a modification of
+		 *  Gauss elimination where the division by the pivot element is
+		 *  <EM>delayed</EM> until it can be carried out without computing
+		 *  GCDs.  If \f$m_{i,j}^{(0)}\f$ are the entries of the original
+		 *  matrix, then the matrix is transformed into triangular form by
+		 *  applying the rules
+		 *  \f[
+		 *      m_{i,j}^{(k+1)} = (m_{i,j}^{(k)} m_{k,k}^{(k)} - m_{i,k}^{(k)} m_{k,j}^{(k)}) / m_{k-1,k-1}^{(k-1)}
+		 *  \f]
+		 *  (We have set \f$m_{-1,-1}^{(-1)}=1\f$ in order to avoid a case
+		 *  distinction in above formula.)  It can be shown that nothing more
+		 *  than polynomial long division is needed for carrying out the
+		 *  division.  This is generally the fastest algorithm for solving
+		 *  linear systems.  In contrast to division-free elimination it only
+		 *  has a linear expression swell.  For two-dimensional systems, the
+		 *  two algorithms are equivalent, however. */
 		bareiss
 	};
 };
 
+/** Flags to store information about the state of an object.
+ *  @see basic::flags */
 class status_flags {
 public:
 	enum {
-		dynallocated    = 0x0001,
-		evaluated       = 0x0002,
-		expanded        = 0x0004,
-		hash_calculated = 0x0008
+		dynallocated    = 0x0001, ///< heap-allocated (i.e. created by new if we want to be clever and bypass the stack, @see ex::construct_from_basic() )
+		evaluated       = 0x0002, ///< .eval() has already done its job
+		expanded        = 0x0004, ///< .expand(0) has already done its job (other expand() options ignore this flag)
+		hash_calculated = 0x0008, ///< .calchash() has already done its job
+		not_shareable   = 0x0010  ///< don't share instances of this object between different expressions unless explicitly asked to (used by ex::compare())
 	};
 };
 
@@ -125,13 +227,7 @@ public:
 		has_indices,  // object has at least one index
 
 		// answered by class idx
-		idx,
-
-		// answered by class coloridx
-		coloridx,
-
-		// answered by class lorentzidx
-		lorentzidx
+		idx
 	};
 };
 
@@ -144,27 +240,18 @@ public:
 	};
 };
 
-class csrc_types {
-public:
-	enum {
-		ctype_float,
-		ctype_double,
-		ctype_cl_N
-	};
-};
-
+/** Strategies how to clean up the function remember cache.
+ *  @see remember_table */
 class remember_strategies {
 public:
 	enum {
-		delete_never, // let table grow undefinitely, not recommmended, but currently default
-		delete_lru,   // least recently used
-		delete_lfu,   // least frequently used
-		delete_cyclic // first (oldest) one in list
+		delete_never,   ///< Let table grow undefinitely
+		delete_lru,     ///< Least recently used
+		delete_lfu,     ///< Least frequently used
+		delete_cyclic   ///< First (oldest) one in list
 	};
 };
 
-#ifndef NO_NAMESPACE_GINAC
 } // namespace GiNaC
-#endif // ndef NO_NAMESPACE_GINAC
 
 #endif // ndef __GINAC_FLAGS_H__