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source: Sophya/trunk/SophyaLib/TArray/basarr.cc@ 975

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Last change on this file since 975 was 958, checked in by ansari, 26 years ago
doc + vire warning cmv 18/04/00
File size: 18.3 KB

Rev	Line
[787]	1	// Base class for numerical arrays
	2	// R. Ansari, C.Magneville 03/2000
	3
	4	#include "machdefs.h"
	5	#include <stdio.h>
	6	#include <stdlib.h>
	7	#include "pexceptions.h"
	8	#include "basarr.h"
	9
[926]	10	/*!
	11	\class SOPHYA::BaseArray
	12	\ingroup TArray
	13	Base class for template arrays
	14	No data are connected to this class.
	15
	16	Define base methods, enum and defaults for TArray , TMatrix and TVector.
	17	*/
	18
[787]	19	// Variables statiques globales
[894]	20	char * BaseArray::ck_op_msg_[6] =
	21	{"???", "Size(int )", "IsPacked(int )"
	22	,"Stride(int )", "ElemCheckBound()", "operator()" };
[787]	23	uint_4 BaseArray::max_nprt_ = 50;
[813]	24	uint_4 BaseArray::prt_lev_ = 0;
[804]	25	short BaseArray::default_memory_mapping = CMemoryMapping;
[813]	26	short BaseArray::default_vector_type = ColumnVector;
	27	uint_8 BaseArray::openmp_size_threshold = 200000;
[787]	28
[813]	29	// ------ Methodes statiques globales --------
	30
[890]	31	//! Set maximum number of printed elements and print level
	32	/*!
	33	\param nprt : maximum number of print
	34	\param lev : print level
	35	*/
[813]	36	void BaseArray::SetMaxPrint(uint_4 nprt, uint_4 lev)
[787]	37	{
	38	max_nprt_ = nprt;
[813]	39	prt_lev_ = (lev < 3) ? lev : 3;
[787]	40	}
	41
[890]	42	//! Set Size threshold for parallel routine call
	43	/*!
	44	\param thr : thresold value
	45	*/
[813]	46	void BaseArray::SetOpenMPSizeThreshold(uint_8 thr)
	47	{
	48	openmp_size_threshold = thr;
	49	}
[787]	50
[813]	51
[894]	52	//! Compute totale size
	53	/*!
	54	\param ndim : number of dimensions
	55	\param siz : array of size along the \b ndim dimensions
	56	\param step[ndim] : step value
	57	\param offset : offset value
	58	\return Total size of the array
	59	*/
[804]	60	uint_8 BaseArray::ComputeTotalSize(uint_4 ndim, const uint_4 * siz, uint_4 step, uint_8 offset)
[787]	61	{
	62	uint_8 rs = step;
[958]	63	for(uint_4 k=0; k<ndim; k++) rs *= siz[k];
[787]	64	return(rs+offset);
	65	}
	66
[894]	67	//! Set Default Memory Mapping
	68	/*!
	69	\param mm : Memory Mapping type
	70	\verbatim
	71	mm == CMemoryMapping : C like memory mapping
	72	mm == FortranMemoryMapping : Fortran like memory mapping
	73	\endverbatim
	74	\verbatim
	75	# ===== For Matrices
	76	*** MATHEMATICS: m(row,column) with indexes running [1,n])
	77	\| 11 12 13 \|
	78	matrix Math = Mmath= \| 21 22 23 \|
	79	\| 31 32 33 \|
	80	*** IDL, \b FORTRAN: indexes data in \b row-major format:
	81	indexes arrays in (column,row) order.
	82	index IDL running [0,n[ ; index FORTRAN running [1,n]
	83	M in memory: [ 11 12 13 : 21 22 23 : 31 32 33 : ... ]
	84	line 1 : line 2 : line 3 : ...
	85	ex: Midl(0,2) = Mfor(1,3) = Mmath(3,1) = 31
	86	Midl(2,0) = Mfor(3,1) = Mmath(1,3) = 13
	87	*** C: indexes data in \b column-major format:
	88	indexes arrays in [row][column] order.
	89	index C running [0,n[
	90	M in memory: [ 11 21 31 : 12 22 32 : 13 23 33 : ... ]
	91	column 1 : column 2 : column 3 : ...
	92	ex: Mc[2][0] = Mmath(3,1) = 31
	93	Mc[0][2] = Mmath(1,3) = 13
	94	*** RESUME diff Idl/Fortan/C/Math:
	95	Midl(col-1,row-1) = Mfor(col,row) = Mc[row-1][col-1] = Mmath(row,col)
	96	TRANSPOSE(column-major array) --> row-major array
	97	\endverbatim
	98	\return default memory mapping value
	99	*/
[804]	100	short BaseArray::SetDefaultMemoryMapping(short mm)
	101	{
[813]	102	default_memory_mapping = (mm != CMemoryMapping) ? FortranMemoryMapping : CMemoryMapping;
[804]	103	return default_memory_mapping;
	104	}
	105
[894]	106	//! Set Default Vector Type
	107	/*!
	108	\param vt : vector type (ColumnVector,RowVector)
	109	\return default vector type value
	110	*/
[813]	111	short BaseArray::SetDefaultVectorType(short vt)
	112	{
	113	default_vector_type = (vt != ColumnVector) ? RowVector : ColumnVector ;
	114	return default_vector_type;
	115	}
[804]	116
[894]	117	//! Select Memory Mapping
	118	/*!
	119	Do essentially nothing.
	120	\param mm : type of Memory Mapping (CMemoryMapping,FortranMemoryMapping)
	121	\return return \b mm if it makes sense or default memory mapping value
	122	\sa SetDefaultMemoryMapping
	123	*/
[804]	124	short BaseArray::SelectMemoryMapping(short mm)
	125	{
	126	if ( (mm == CMemoryMapping) \|\| (mm == FortranMemoryMapping) ) return (mm) ;
	127	else return (default_memory_mapping);
	128	}
[894]	129
	130	//! Select Vector type
	131	/*!
	132	Do essentially nothing.
	133	\param vt : vector type (ColumnVector,RowVector)
	134	\return return \b vt if it makes sense or default vector type
	135	\sa SetDefaultVectorType
	136	*/
[813]	137	short BaseArray::SelectVectorType(short vt)
	138	{
	139	if ((vt == ColumnVector) \|\| (vt == RowVector)) return(vt);
	140	else return(default_vector_type);
	141	}
[804]	142
[894]	143	//! Update Memory Mapping
	144	/*!
	145	Update variables marowi_ macoli_ veceli_
	146	\param mm : type of Memory Mapping (CMemoryMapping,FortranMemoryMapping)
	147	\sa SetDefaultMemoryMapping
	148	*/
[813]	149	void BaseArray::UpdateMemoryMapping(short mm)
[804]	150	{
[813]	151	short vt = default_vector_type;
[804]	152	if ( (mm != CMemoryMapping) && (mm != FortranMemoryMapping) ) mm = default_memory_mapping;
	153	if (mm == CMemoryMapping) {
[813]	154	marowi_ = 1; macoli_ = 0;
[804]	155	}
	156	else {
[813]	157	marowi_ = 0; macoli_ = 1;
	158	}
	159
	160	if ( (ndim_ == 2) && ((size_[0] == 1) \|\| (size_[1] == 1)) ) {
	161	// Choix automatique Vecteur ligne ou colonne
	162	if ( size_[macoli_] == 1) veceli_ = marowi_;
	163	else veceli_ = macoli_;
	164	}
	165	else veceli_ = (vt == ColumnVector ) ? marowi_ : macoli_;
	166	ck_memo_vt_ = true; // Check MemMapping and VectorType for CompareSize
[804]	167	}
	168
[894]	169	//! Update Memory Mapping
	170	/*!
	171	\param a : Array to be compared with
	172	\param mm : type of Memory Mapping or memory mapping transfert
	173	(SameMemoryMapping,AutoMemoryMapping,CMemoryMapping,FortranMemoryMapping)
	174	\sa SetDefaultMemoryMapping
	175	*/
[804]	176	void BaseArray::UpdateMemoryMapping(BaseArray const & a, short mm)
	177	{
[813]	178	short vt = default_vector_type;
	179	if (mm == SameMemoryMapping) {
[804]	180	mm = ((a.marowi_ == 1) ? CMemoryMapping : FortranMemoryMapping);
[813]	181	vt = (a.marowi_ == a.veceli_) ? ColumnVector : RowVector;
	182	}
	183	else if (mm == AutoMemoryMapping) mm = default_memory_mapping;
	184
[804]	185	if ( (mm != CMemoryMapping) && (mm != FortranMemoryMapping) ) mm = default_memory_mapping;
	186	if (mm == CMemoryMapping) {
[813]	187	marowi_ = 1; macoli_ = 0;
[804]	188	}
	189	else {
[813]	190	marowi_ = 0; macoli_ = 1;
	191	}
	192	if ( (ndim_ == 2) && ((size_[0] == 1) \|\| (size_[1] == 1)) ) {
	193	// Choix automatique Vecteur ligne ou colonne
	194	if ( size_[macoli_] == 1) veceli_ = marowi_;
	195	else veceli_ = marowi_;
	196	}
	197	else veceli_ = (vt == ColumnVector ) ? marowi_ : macoli_;
	198	ck_memo_vt_ = true; // Check MemMapping and VectorType for CompareSize
[804]	199	}
	200
[894]	201	//! Set Memory Mapping type
	202	/*!
	203	Compute values for variables marowi_ macoli_ veceli_
	204	\param mm : Memory Mapping type (SameMemoryMapping,AutoMemoryMapping
	205	,CMemoryMapping,FortranMemoryMapping)
	206	\sa SetDefaultMemoryMapping
	207	*/
[813]	208	void BaseArray::SetMemoryMapping(short mm)
	209	{
	210	if (mm == SameMemoryMapping) return;
	211	if (mm == AutoMemoryMapping) mm = default_memory_mapping;
	212	if ( (mm != CMemoryMapping) && (mm != FortranMemoryMapping) ) return;
	213	short vt = (marowi_ == veceli_) ? ColumnVector : RowVector;
	214	if (mm == CMemoryMapping) {
	215	marowi_ = 1; macoli_ = 0;
	216	}
	217	else {
	218	marowi_ = 0; macoli_ = 1;
	219	}
	220	if ( (ndim_ == 2) && ((size_[0] == 1) \|\| (size_[1] == 1)) ) {
	221	// Choix automatique Vecteur ligne ou colonne
	222	if ( size_[macoli_] == 1) veceli_ = marowi_;
	223	else veceli_ = macoli_;
	224	}
	225	else veceli_ = (vt == ColumnVector ) ? marowi_ : macoli_;
	226	ck_memo_vt_ = true; // Check MemMapping and VectorType for CompareSize
	227	}
[804]	228
[894]	229	//! Set Vector Type
	230	/*!
	231	Compute values for variable veceli_
	232	\param vt : vector type ()
	233	\sa SetDefaultVectorType
	234	*/
[813]	235	void BaseArray::SetVectorType(short vt)
	236	{
	237	if (vt == SameVectorType) return;
	238	if (vt == AutoVectorType) vt = default_vector_type;
	239	if ( (ndim_ == 2) && ((size_[0] == 1) \|\| (size_[1] == 1)) ) {
	240	// Choix automatique Vecteur ligne ou colonne
	241	if ( size_[macoli_] == 1) veceli_ = marowi_;
	242	else veceli_ = macoli_;
	243	}
	244	else veceli_ = (vt == ColumnVector ) ? marowi_ : macoli_;
	245	ck_memo_vt_ = true; // Check MemMapping and VectorType for CompareSize
	246	}
	247
[787]	248	// -------------------------------------------------------
	249	// Methodes de la classe
	250	// -------------------------------------------------------
	251
[890]	252	//! Default constructor
[787]	253	BaseArray::BaseArray()
	254	: mInfo(NULL)
	255	{
	256	ndim_ = 0;
	257	for(int k=0; k<BASEARRAY_MAXNDIMS; k++) step_[k] = size_[k] = 0;
	258	totsize_ = 0;
	259	minstep_ = 0;
	260	moystep_ = 0;
	261	offset_ = 0;
[813]	262	// Default for matrices : Memory organisation and Vector type
	263	if (default_memory_mapping == CMemoryMapping) {
	264	marowi_ = 1; macoli_ = 0;
	265	}
	266	else {
	267	marowi_ = 0; macoli_ = 1;
	268	}
	269	veceli_ = (default_vector_type == ColumnVector ) ? marowi_ : macoli_;
	270	ck_memo_vt_ = false; // Default : Don't Check MemMapping and VectorType for CompareSize
[787]	271	}
	272
[890]	273	//! Destructor
[787]	274	BaseArray::~BaseArray()
	275	{
	276	}
	277
	278
[894]	279	//! Returns true if dimension and sizes are equal
[890]	280	/*!
	281	\param a : array to be compared
[894]	282	\return true if ndim and sizes[ndim] are equal, false if not
[890]	283	*/
[787]	284	bool BaseArray::CompareSizes(const BaseArray& a)
	285	{
	286	if (ndim_ != a.ndim_) return(false);
[958]	287	for(uint_4 k=0; k<ndim_; k++)
[787]	288	if (size_[k] != a.size_[k]) return(false);
[813]	289	// $CHECK$ Reza doit-on verifier ca
	290	if (ck_memo_vt_ && a.ck_memo_vt_)
	291	if ( (macoli_ != a.macoli_) \|\| (marowi_ != a.marowi_) \|\|
	292	(veceli_ != a.veceli_) ) return(false);
[787]	293	return(true);
	294	}
	295
[894]	296	//! Change dimension if some size == 1
[787]	297	void BaseArray::CompactAllDim()
	298	{
	299	if (ndim_ < 2) return;
	300	uint_4 ndim = 0;
	301	uint_4 size[BASEARRAY_MAXNDIMS];
	302	uint_4 step[BASEARRAY_MAXNDIMS];
[958]	303	for(uint_4 k=0; k<ndim_; k++) {
[787]	304	if (size_[k] < 2) continue;
	305	size[ndim] = size_[k];
	306	step[ndim] = step_[k];
	307	ndim++;
	308	}
	309	if (ndim == 0) {
	310	size[0] = size_[0];
	311	step[0] = step_[0];
	312	ndim = 1;
	313	}
	314	string exmsg = "BaseArray::CompactAllDim() ";
	315	if (!UpdateSizes(ndim, size, step, offset_, exmsg)) throw( ParmError(exmsg) );
	316	return;
	317	}
	318
[894]	319	//! Change dimension if some trailed size == 1
[787]	320	void BaseArray::CompactTrailingDim()
	321	{
	322	if (ndim_ < 2) return;
	323	uint_4 ndim = 0;
	324	uint_4 size[BASEARRAY_MAXNDIMS];
	325	uint_4 step[BASEARRAY_MAXNDIMS];
[958]	326	for(uint_4 k=0; k<ndim_; k++) {
[787]	327	size[ndim] = size_[k];
	328	step[ndim] = step_[k];
	329	if (size_[k] > 1) ndim=k;
	330	}
	331	if (ndim == 0) ndim = 1;
	332	string exmsg = "BaseArray::CompactTrailingDim() ";
	333	if (!UpdateSizes(ndim, size, step, offset_, exmsg)) throw( ParmError(exmsg) );
	334	return;
	335	}
	336
[894]	337	//! return minimum value for step[ndim]
[787]	338	uint_4 BaseArray::MinStepKA() const
	339	{
[958]	340	for(uint_4 ka=0; ka<ndim_; ka++)
[787]	341	if (step_[ka] == minstep_) return(ka);
	342	return(0);
	343	}
	344
[894]	345	//! return maximum value for step[ndim]
[787]	346	uint_4 BaseArray::MaxSizeKA() const
	347	{
	348	uint_4 ka = 0;
	349	uint_4 mx = size_[0];
[958]	350	for(uint_4 k=0; k<ndim_; k++)
[787]	351	if (size_[k] > mx) { ka = k; mx = size_[k]; }
	352	return(ka);
	353	}
	354
	355
	356	// Acces lineaire aux elements .... Calcul d'offset
[813]	357	// --------------------------------------------------
	358	// Position de l'element 0 du vecteur i selon l'axe ka
	359	// --------------------------------------------------
[894]	360	//! return position of first element for vector \b i alond \b ka th axe.
[813]	361	uint_8 BaseArray::Offset(uint_4 ka, uint_8 i) const
	362	{
[787]	363
[813]	364	if ( (ndim_ < 1) \|\| (i == 0) ) return(offset_);
	365	//#ifdef SO_BOUNDCHECKING
	366	if (ka >= ndim_)
	367	throw RangeCheckError("BaseArray::Offset(uint_4 ka, uint_8 i) Axe KA Error");
	368	if ( i*size_[ka] >= totsize_ )
	369	throw RangeCheckError("BaseArray::Offset(uint_4 ka, uint_8 i) Index Error");
	370	//#endif
	371	uint_4 idx[BASEARRAY_MAXNDIMS];
[958]	372	uint_4 k;
[813]	373	uint_8 rest = i;
	374	idx[ka] = 0;
	375	for(k=0; k<ndim_; k++) {
	376	if (k == ka) continue;
	377	idx[k] = rest%size_[k]; rest /= size_[k];
	378	}
	379	uint_8 off = offset_;
	380	for(k=0; k<ndim_; k++) off += idx[k]*step_[k];
	381	return (off);
	382	}
	383
[894]	384	//! return position of element \b ip.
[787]	385	uint_8 BaseArray::Offset(uint_8 ip) const
	386	{
[813]	387	if ( (ndim_ < 1) \|\| (ip == 0) ) return(offset_);
	388	//#ifdef SO_BOUNDCHECKING
	389	if (ip >= totsize_)
	390	throw RangeCheckError("BaseArray::Offset(uint_8 ip) Out of range index ip");
	391	//#endif
	392
	393	uint_4 idx[BASEARRAY_MAXNDIMS];
[958]	394	uint_4 k;
[813]	395	uint_8 rest = ip;
	396	for(k=0; k<ndim_; k++) {
	397	idx[k] = rest%size_[k]; rest /= size_[k];
	398	}
	399	//#ifdef SO_BOUNDCHECKING
	400	if (rest != 0)
	401	throw PError("BaseArray::Offset(uint_8 ip) GUG !!! rest != 0");
	402	//#endif
	403	// if (rest != 0) cerr << " BUG ---- BaseArray::Offset( " << ip << " )" << rest << endl;
	404	// cerr << " DBG-Offset( " << ip << ")" ;
	405	// for(k=0; k<ndim_; k++) cerr << idx[k] << "," ;
	406	// cerr << " ZZZZ " << endl;
	407	uint_8 off = offset_;
	408	for(k=0; k<ndim_; k++) off += idx[k]*step_[k];
	409	return (off);
[787]	410	}
	411
	412
	413	// ----------------------------------------------------
	414	// Impression, etc ...
	415	// ----------------------------------------------------
	416
[894]	417	//! Show infos on stream \b os (\b si to display DvList)
[787]	418	void BaseArray::Show(ostream& os, bool si) const
	419	{
[850]	420	if (ndim_ < 1) {
	421	os << "\n--- " << BaseArray::InfoString() << " Unallocated Array ! " << endl;
	422	return;
	423	}
[813]	424	os << "\n--- " << InfoString() ;
	425	os << " ND=" << ndim_ << " SizeXY...= " ;
[958]	426	for(uint_4 k=0; k<ndim_; k++) {
[787]	427	os << size_[k];
[813]	428	if (k<ndim_-1) os << "x";
[787]	429	}
[813]	430	os << " ---" << endl;
	431	if (prt_lev_ > 0) {
	432	os << " TotSize= " << totsize_ << " Step(X Y ...)=" ;
[958]	433	for(uint_4 k=0; k<ndim_; k++) os << step_[k] << " " ;
[813]	434	os << " Offset= " << offset_ << endl;
	435	}
	436	if (prt_lev_ > 1) {
	437	os << " MemoryMapping=" << GetMemoryMapping() << " VecType= " << GetVectorType()
	438	<< " RowsKA= " << RowsKA() << " ColsKA= " << ColsKA()
	439	<< " VectKA=" << VectKA() << endl;
	440	}
	441	if (!si && (prt_lev_ < 2)) return;
	442	if (mInfo != NULL) os << (*mInfo) << endl;
[787]	443
	444	}
	445
[894]	446	//! Return BaseArray Type
[813]	447	string BaseArray::InfoString() const
	448	{
	449	string rs = "BaseArray Type= ";
	450	rs += typeid(*this).name() ;
	451	return rs;
	452	}
[787]	453
[894]	454	//! Return attached DVList
[787]	455	DVList& BaseArray::Info()
	456	{
	457	if (mInfo == NULL) mInfo = new DVList;
	458	return(*mInfo);
	459	}
	460
[894]	461	//! Update sizes and information for array
	462	/*!
	463	\param ndim : dimension
	464	\param siz[ndim] : sizes
	465	\param step : step (must be the same on all dimensions)
	466	\param offset : offset of the first element
	467	\return true if all OK, false if problems appear
	468	\return string \b exmsg for explanation in case of problems
	469	*/
[787]	470	bool BaseArray::UpdateSizes(uint_4 ndim, const uint_4 * siz, uint_4 step, uint_8 offset, string & exmsg)
	471	{
	472	if (ndim >= BASEARRAY_MAXNDIMS) {
	473	exmsg += " NDim Error"; return false;
	474	}
	475	if (step < 1) {
	476	exmsg += " Step(=0) Error"; return false;
	477	}
	478
	479	minstep_ = moystep_ = step;
	480
	481	// Flagging bad updates ...
	482	ndim_ = 0;
	483
	484	totsize_ = 1;
[958]	485	uint_4 k;
[787]	486	for(k=0; k<BASEARRAY_MAXNDIMS; k++) {
	487	size_[k] = 1;
	488	step_[k] = 0;
	489	}
	490	for(k=0; k<ndim; k++) {
	491	size_[k] = siz[k] ;
	492	step_[k] = totsize_*step;
	493	totsize_ *= size_[k];
	494	}
	495	if (totsize_ < 1) {
	496	exmsg += " Size Error"; return false;
	497	}
	498	offset_ = offset;
[813]	499	// Default for matrices : Memory organisation and Vector type
	500	if (default_memory_mapping == CMemoryMapping) {
	501	marowi_ = 1; macoli_ = 0;
	502	}
	503	else {
	504	marowi_ = 0; macoli_ = 1;
	505	}
	506	veceli_ = (default_vector_type == ColumnVector ) ? marowi_ : macoli_;
	507	ck_memo_vt_ = false; // Default : Don't Check MemMapping and VectorType for CompareSize
[787]	508	// Update OK
	509	ndim_ = ndim;
	510	return true;
	511	}
	512
[894]	513	//! Update sizes and information for array
	514	/*!
	515	\param ndim : dimension
	516	\param siz[ndim] : sizes
	517	\param step[ndim] : steps
	518	\param offset : offset of the first element
	519	\return true if all OK, false if problems appear
	520	\return string \b exmsg for explanation in case of problems
	521	*/
[787]	522	bool BaseArray::UpdateSizes(uint_4 ndim, const uint_4 * siz, const uint_4 * step, uint_8 offset, string & exmsg)
	523	{
	524	if (ndim >= BASEARRAY_MAXNDIMS) {
	525	exmsg += " NDim Error"; return false;
	526	}
	527
	528	// Flagging bad updates ...
	529	ndim_ = 0;
	530
	531	totsize_ = 1;
[958]	532	uint_4 k;
[787]	533	for(k=0; k<BASEARRAY_MAXNDIMS; k++) {
	534	size_[k] = 1;
	535	step_[k] = 0;
	536	}
	537	uint_4 minstep = step[0];
	538	for(k=0; k<ndim; k++) {
	539	size_[k] = siz[k] ;
	540	step_[k] = step[k];
	541	totsize_ *= size_[k];
	542	if (step_[k] < minstep) minstep = step_[k];
	543	}
	544	if (minstep < 1) {
	545	exmsg += " Step(=0) Error"; return false;
	546	}
	547	if (totsize_ < 1) {
	548	exmsg += " Size Error"; return false;
	549	}
	550	uint_8 plast = 0;
	551	for(k=0; k<ndim; k++) plast += (siz[k]-1)*step[k];
	552	if (plast == minstep*totsize_ ) moystep_ = minstep;
	553	else moystep_ = 0;
	554	minstep_ = minstep;
	555	offset_ = offset;
[813]	556	// Default for matrices : Memory organisation and Vector type
	557	if (default_memory_mapping == CMemoryMapping) {
	558	marowi_ = 1; macoli_ = 0;
	559	}
	560	else {
	561	marowi_ = 0; macoli_ = 1;
	562	}
	563	veceli_ = (default_vector_type == ColumnVector ) ? marowi_ : macoli_;
	564	ck_memo_vt_ = false; // Default : Don't Check MemMapping and VectorType for CompareSize
[787]	565	// Update OK
	566	ndim_ = ndim;
	567	return true;
	568	}
	569
[894]	570	//! Update sizes and information relative to array \b a
	571	/*!
	572	\param a : array to be compare with
	573	\return true if all OK, false if problems appear
	574	\return string \b exmsg for explanation in case of problems
	575	*/
[787]	576	bool BaseArray::UpdateSizes(const BaseArray& a, string & exmsg)
	577	{
	578	if (a.ndim_ >= BASEARRAY_MAXNDIMS) {
	579	exmsg += " NDim Error"; return false;
	580	}
	581
	582	// Flagging bad updates ...
	583	ndim_ = 0;
	584
	585	totsize_ = 1;
[958]	586	uint_4 k;
[787]	587	for(k=0; k<BASEARRAY_MAXNDIMS; k++) {
	588	size_[k] = 1;
	589	step_[k] = 0;
	590	}
	591	uint_4 minstep = a.step_[0];
	592	for(k=0; k<a.ndim_; k++) {
	593	size_[k] = a.size_[k] ;
	594	step_[k] = a.step_[k];
	595	totsize_ *= size_[k];
	596	if (step_[k] < minstep) minstep = step_[k];
	597	}
	598	if (minstep < 1) {
	599	exmsg += " Step(=0) Error"; return false;
	600	}
	601	if (totsize_ < 1) {
	602	exmsg += " Size Error"; return false;
	603	}
	604
	605	minstep_ = a.minstep_;
	606	moystep_ = a.moystep_;
	607	offset_ = a.offset_;
	608	macoli_ = a.macoli_;
	609	marowi_ = a.marowi_;
[804]	610	veceli_ = a.veceli_;
[813]	611	ck_memo_vt_ = a.ck_memo_vt_;
[787]	612	// Update OK
	613	ndim_ = a.ndim_;
	614	return true;
	615	}
	616
	617
[894]	618	//! Update sizes and information relative to array \b a
	619	/*!
	620	\param a : array to be compare with
	621	\param ndim : could be change (but should be less than the ndim of the current class)
	622	\param siz[ndim],pos[ndim],step[ndim] : could be changed but must be
	623	compatible within the memory size with those of the current class.
	624	\return true if all OK, false if problems appear
	625	\return string \b exmsg for explanation in case of problems
	626	*/
[804]	627	void BaseArray::UpdateSubArraySizes(BaseArray & ra, uint_4 ndim, uint_4 * siz, uint_4 * pos, uint_4 * step) const
[787]	628	{
[804]	629	if ( (ndim > ndim_) \|\| (ndim < 1) )
	630	throw(SzMismatchError("BaseArray::UpdateSubArraySizes( ... ) NDim Error") );
[958]	631	uint_4 k;
[787]	632	for(k=0; k<ndim; k++)
	633	if ( (siz[k]*step[k]+pos[k]) > size_[k] )
[804]	634	throw(SzMismatchError("BaseArray::UpdateSubArraySizes( ... ) Size/Pos Error") );
[787]	635	uint_8 offset = offset_;
	636	for(k=0; k<ndim_; k++) {
	637	offset += pos[k]*step_[k];
	638	step[k] *= step_[k];
	639	}
[804]	640	string exm = "BaseArray::UpdateSubArraySizes() ";
[787]	641	if (!ra.UpdateSizes(ndim, siz, step, offset, exm))
	642	throw( ParmError(exm) );
	643	return;
	644	}
	645
	646

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