Gauss 11 User Manual

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Gauss 11 User Manual | Manualzz
TM
GAUSS
User Guide
Aptech Systems, Inc. — Mathematical and Statistical System
Information in this document is subject to change without notice and does not represent
a commitment on the part of Aptech Systems, Inc. The software described in this
document is furnished under a license agreement or nondisclosure agreement. The
software may be used or copied only in accordance with the terms of the agreement.
The purchaser may make one copy of the software for backup purposes. No part of
this manual may be reproduced or transmitted in any form or by any means, electronic
or mechanical, including photocopying and recording, for any purpose other than the
purchaser’s personal use without the written permission of Aptech Systems, Inc.
c
Copyright
Aptech Systems, Inc. Black Diamond WA 1984-2010
All Rights Reserved Worldwide.
c
SuperLU. Copyright
2003, The Regents of the University of California, through
Lawrence Berkeley National Laboratory (subject to receipt of any required approvals
from U.S. Dept. of Energy). All Rights Reserved. See GAUSS Software Product
License for additional terms and conditions.
c
TAUCS Version 2.0, November 29, 2001. Copyright
2001, 2002, 2003 by Sivan
Toledo, Tel-Aviv University, [email protected]. All Rights Reserved. See GAUSS
Software License for additional terms and conditions.
Econotron Software, Inc. beta, polygamma, zeta, gammacplx, lngammacplx, erfcplx,
c
erfccplx, psi, gradcp, hesscp Functions: Copyright
2009 by Econotron Software,
Inc. All Rights Reserved Worldwide.
GAUSS, GAUSS Engine and GAUSS Light are trademarks of Aptech Systems, Inc.
GEM is a trademark of Digital Research, Inc.
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Other trademarks are the property of their respective owners.
Part Number: 007431
Version 11
Documentation Revision: 1032
October 22, 2010
Contents
Contents
1 Introduction
1.1
Product Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
1-1
1.2
Documentation Conventions
. . . . . . . . . . . . . . . . . . . . . . . . . . .
1-2
2.1
Installation Under UNIX/Linux . . . . . . . . . . . . . . . . . . . . . . . . . . .
2-1
2.2
Installation Under Windows . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2-2
2.2.1
Machine Requirements . . . . . . . . . . . . . . . . . . . . . . . . .
2-2
2.2.2
Installation from Download . . . . . . . . . . . . . . . . . . . . . . .
2-2
2.2.3
Installation from CD . . . . . . . . . . . . . . . . . . . . . . . . . . .
2-2
2 Getting Started
3 Introduction to the GAUSS Graphical User Interface
3.1
Page Organization Concept . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3.2
Command Page . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3-2
3.2.1
Menus and Toolbars . . . . . . . . . . . . . . . . . . . . . . . . . . .
3-3
3.2.2
Command Page Toolbar . . . . . . . . . . . . . . . . . . . . . . . . .
3-4
3.2.3
Working Directory Toolbar . . . . . . . . . . . . . . . . . . . . . . . .
3-4
3.2.4
Command History Toolbar . . . . . . . . . . . . . . . . . . . . . . . .
3-5
3.2.5
The Run, Debug, and Edit Buttons . . . . . . . . . . . . . . . . . . .
3-6
Layout . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3-6
3.3.1
Command History Window . . . . . . . . . . . . . . . . . . . . . . .
3-7
3.3.2
The Command Input Window . . . . . . . . . . . . . . . . . . . . . .
3-8
Command Line History and Command Line Editing . . . . . . . . . . . . . . .
3-8
3.4.1
Movement . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3-8
3.4.2
Error Output Window . . . . . . . . . . . . . . . . . . . . . . . . . .
3-9
Source Page: Editing Programs . . . . . . . . . . . . . . . . . . . . . . . . . .
3-9
3.5.1
Menus and Toolbars . . . . . . . . . . . . . . . . . . . . . . . . . . .
3-9
3.5.2
Layout and Usage . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3-10
3.3
3.4
3.5
3-1
v
GAUSS User Guide
3.6
3.7
3.8
3.5.3
Find and Replace . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3-14
3.5.4
Changing Editor Properties . . . . . . . . . . . . . . . . . . . . . . .
3-15
3.5.5
Command Input Window . . . . . . . . . . . . . . . . . . . . . . . .
3-16
3.5.6
Error Output Window . . . . . . . . . . . . . . . . . . . . . . . . . .
3-16
Data Page . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3-16
3.6.1
Menu Bar . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3-16
3.6.2
Layout . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3-18
3.6.3
Symbol Editor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3-20
Debug Page . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3-20
3.7.1
Menus and Toolbars . . . . . . . . . . . . . . . . . . . . . . . . . . .
3-20
3.7.2
Using Breakpoints . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3-22
3.7.3
Setting and Clearing Breakpoints . . . . . . . . . . . . . . . . . . . .
3-23
3.7.4
Stepping Through a Program . . . . . . . . . . . . . . . . . . . . . .
3-23
3.7.5
Viewing and Editing Variables . . . . . . . . . . . . . . . . . . . . . .
3-23
Help Page . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3-25
3.8.1
3-25
Hot Keys . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
4 Navigating the GAUSS Graphical User Interface
4.1
Hot Keys and Shortcuts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
4-2
4.2
Navigating Between Pages . . . . . . . . . . . . . . . . . . . . . . . . . . . .
4-2
4.3
Switch To Command Page on I/O . . . . . . . . . . . . . . . . . . . . . . . . .
4-3
4.4
Viewing Program Output from Other Pages
. . . . . . . . . . . . . . . . . . .
4-3
4.5
F1 Help . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
4-4
4.6
CTRL+F1 Source Browsing . . . . . . . . . . . . . . . . . . . . . . . . . . . .
4-4
5 Using the Command Line Interface
5.1
Viewing Graphics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5-2
5.2
Command Line History and Command Line Editing . . . . . . . . . . . . . . .
5-2
5.2.1
Movement . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5-2
5.2.2
Editing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5-3
5.2.3
History Retrieval . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5-3
vi
Contents
5.3
5.4
5.5
Interactive Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5-4
5.3.1
quit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5-4
5.3.2
ed . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5-5
5.3.3
browse . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5-5
5.3.4
config . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5-5
Debugging . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5-7
5.4.1
General Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5-7
5.4.2
Listing Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5-7
5.4.3
Execution Functions . . . . . . . . . . . . . . . . . . . . . . . . . . .
5-7
5.4.4
View Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5-9
5.4.5
Breakpoint Commands . . . . . . . . . . . . . . . . . . . . . . . . .
5-9
Using the Source Browser in TGAUSS . . . . . . . . . . . . . . . . . . . . . .
5-10
6 Language Fundamentals
6.1
Expressions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6.2
Statements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6-2
6.2.1
Executable Statements . . . . . . . . . . . . . . . . . . . . . . . . .
6-3
6.2.2
Nonexecutable Statements . . . . . . . . . . . . . . . . . . . . . . .
6-3
Programs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6-4
6.3.1
Main Section . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6-4
6.3.2
Secondary Sections . . . . . . . . . . . . . . . . . . . . . . . . . . .
6-5
6.4
Compiler Directives . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6-5
6.5
Procedures . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6-8
6.6
Data Types . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6-9
6.6.1
Constants . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6-9
6.6.2
Matrices . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6-11
6.6.3
Sparse Matrices . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6-18
6.6.4
N-dimensional Arrays . . . . . . . . . . . . . . . . . . . . . . . . . .
6-19
6.6.5
Strings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6-20
6.6.6
String Arrays . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6-24
6.6.7
Character Matrices . . . . . . . . . . . . . . . . . . . . . . . . . . .
6-26
6.6.8
Date and Time Formats . . . . . . . . . . . . . . . . . . . . . . . . .
6-27
6.3
6-1
vii
GAUSS User Guide
6.6.9
Special Data Types . . . . . . . . . . . . . . . . . . . . . . . . . . .
6-28
6.7
Operator Precedence . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6-30
6.8
Flow Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6-31
6.8.1
Looping
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6-32
6.8.2
Conditional Branching . . . . . . . . . . . . . . . . . . . . . . . . . .
6-34
6.8.3
Unconditional Branching
. . . . . . . . . . . . . . . . . . . . . . . .
6-35
Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6-37
6.10 Rules of Syntax . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6-37
6.9
6.10.1
Statements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6-37
6.10.2
Case . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6-38
6.10.3
Comments . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6-38
6.10.4
Extraneous Spaces . . . . . . . . . . . . . . . . . . . . . . . . . . .
6-38
6.10.5
Symbol Names
. . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6-39
6.10.6
Labels . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6-39
6.10.7
Assignment Statements . . . . . . . . . . . . . . . . . . . . . . . . .
6-39
6.10.8
Function Arguments . . . . . . . . . . . . . . . . . . . . . . . . . . .
6-40
6.10.9
Indexing Matrices . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6-40
6.10.10 Arrays of Matrices and Strings . . . . . . . . . . . . . . . . . . . . .
6-41
6.10.11 Arrays of Procedures . . . . . . . . . . . . . . . . . . . . . . . . . .
6-42
7 Operators
7.1
Element-by-Element Operators . . . . . . . . . . . . . . . . . . . . . . . . . .
7-1
7.2
Matrix Operators . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
7-4
7.2.1
Numeric Operators . . . . . . . . . . . . . . . . . . . . . . . . . . .
7-4
7.2.2
Other Matrix Operators . . . . . . . . . . . . . . . . . . . . . . . . .
7-8
7.3
Relational Operators . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
7-9
7.4
Logical Operators . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
7-13
7.5
Other Operators . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
7-15
7.6
Using Dot Operators with Constants . . . . . . . . . . . . . . . . . . . . . . .
7-20
7.7
Operator Precedence . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
7-22
viii
Contents
8 Procedures and Keywords
8.1
Defining a Procedure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
8-2
8.1.1
Procedure Declaration . . . . . . . . . . . . . . . . . . . . . . . . . .
8-3
8.1.2
Local Variable Declarations . . . . . . . . . . . . . . . . . . . . . . .
8-3
8.1.3
Body of Procedure . . . . . . . . . . . . . . . . . . . . . . . . . . . .
8-4
8.1.4
Returning from the Procedure . . . . . . . . . . . . . . . . . . . . . .
8-5
8.1.5
End of Procedure Definition . . . . . . . . . . . . . . . . . . . . . . .
8-5
8.2
Calling a Procedure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
8-6
8.3
Keywords . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
8-7
8.3.1
Defining a Keyword . . . . . . . . . . . . . . . . . . . . . . . . . . .
8-7
8.3.2
Calling a Keyword . . . . . . . . . . . . . . . . . . . . . . . . . . . .
8-8
8.4
Passing Procedures to Procedures . . . . . . . . . . . . . . . . . . . . . . . .
8-9
8.5
Indexing Procedures . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
8-10
8.6
Multiple Returns from Procedures
. . . . . . . . . . . . . . . . . . . . . . . .
8-11
8.7
Saving Compiled Procedures . . . . . . . . . . . . . . . . . . . . . . . . . . .
8-13
9 Sparse Matrices
9.1
Defining Sparse Matrices . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
9-1
9.2
Creating and Using Sparse Matrices . . . . . . . . . . . . . . . . . . . . . . .
9-2
9.3
Sparse Support in Matrix Functions and Operators . . . . . . . . . . . . . . .
9-3
9.3.1
9-5
Return Types for Dyadic Operators . . . . . . . . . . . . . . . . . . .
10 N-Dimensional Arrays
10.1 Bracketed Indexing
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
10-3
10.2 E×E Conformability . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
10-5
10.3 Glossary of Terms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
10-5
11 Working with Arrays
11.1 Initializing Arrays . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11.1.1
areshape . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11-1
11-2
ix
GAUSS User Guide
11.1.2
aconcat . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11-4
11.1.3
aeye . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11-6
11.1.4
arrayinit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11-6
11.1.5
arrayalloc . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11-7
11.2 Assigning to Arrays . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11-8
11.2.1
index operator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11-9
11.2.2
getArray . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11-12
11.2.3
getMatrix . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11-13
11.2.4
getMatrix4D . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11-13
11.2.5
getScalar3D, getScalar4D . . . . . . . . . . . . . . . . . . . . . . . .
11-14
11.2.6
putArray . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11-15
11.2.7
setArray . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11-16
11.3 Looping with Arrays . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11-17
11.3.1
loopnextindex . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11-19
11.4 Miscellaneous Array Functions . . . . . . . . . . . . . . . . . . . . . . . . . .
11-21
11.4.1
atranspose . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11-21
11.4.2
amult . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11-23
11.4.3
amean, amin, amax . . . . . . . . . . . . . . . . . . . . . . . . . . .
11-25
11.4.4
getDims . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11-27
11.4.5
getOrders . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11-27
11.4.6
arraytomat . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11-28
11.4.7
mattoarray . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11-28
11.5 Using Arrays with GAUSS functions . . . . . . . . . . . . . . . . . . . . . . .
11-28
11.6 A Panel Data Model . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11-32
11.7 Appendix . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11-35
12 Structures
12.1 Basic Structures . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
x
12-1
12.1.1
Structure Definition . . . . . . . . . . . . . . . . . . . . . . . . . . .
12-1
12.1.2
Declaring an Instance . . . . . . . . . . . . . . . . . . . . . . . . . .
12-2
12.1.3
Initializing an Instance . . . . . . . . . . . . . . . . . . . . . . . . . .
12-3
12.1.4
Arrays of Structures . . . . . . . . . . . . . . . . . . . . . . . . . . .
12-4
Contents
12.1.5
Structure Indexing . . . . . . . . . . . . . . . . . . . . . . . . . . . .
12-5
12.1.6
Saving an Instance to the Disk . . . . . . . . . . . . . . . . . . . . .
12-8
12.1.7
Loading an Instance from the Disk . . . . . . . . . . . . . . . . . . .
12-9
12.1.8
Passing Structures to Procedures
. . . . . . . . . . . . . . . . . . .
12-9
12.2 Structure Pointers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
12-10
12.2.1
Creating and Assigning Structure Pointers . . . . . . . . . . . . . . .
12-10
12.2.2
Structure Pointer References . . . . . . . . . . . . . . . . . . . . . .
12-11
12.2.3
Using Structure Pointers in Procedures
. . . . . . . . . . . . . . . .
12-13
12.3 Special Structures . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
12-15
12.3.1
The DS Structure . . . . . . . . . . . . . . . . . . . . . . . . . . . .
12-15
12.3.2
The PV Structure . . . . . . . . . . . . . . . . . . . . . . . . . . . .
12-16
12.3.3
Miscellaneous PV Procedures . . . . . . . . . . . . . . . . . . . . .
12-20
12.3.4
Control Structures . . . . . . . . . . . . . . . . . . . . . . . . . . . .
12-22
12.4 sqpSolvemt . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
12-23
12.4.1
Input Arguments . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
12-24
12.4.2
Output Argument
. . . . . . . . . . . . . . . . . . . . . . . . . . . .
12-27
12.4.3
Example . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
12-29
12.4.4
The Command File . . . . . . . . . . . . . . . . . . . . . . . . . . .
12-30
13 Run-Time Library Structures
13.1 The PV Parameter Structure . . . . . . . . . . . . . . . . . . . . . . . . . . .
13-1
13.2 Fast Pack Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
13-6
13.3 The DS Data Structure
13-7
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
14 Multi-Threaded Programming in GAUSS
14.1 The Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
14-1
14.2 GAUSS Threading Concepts . . . . . . . . . . . . . . . . . . . . . . . . . . .
14-3
14.3 Coding With Threads . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
14-4
14.4 Coding Restrictions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
14-6
xi
GAUSS User Guide
15 Libraries
15.1 Autoloader . . . . . . . . . . . . . . .
15.1.1 Forward References . . . . .
15.1.2 The Autoloader Search Path
15.2 Global Declaration Files . . . . . . . .
15.3 Troubleshooting . . . . . . . . . . . .
15.3.1 Using .dec Files . . . . . . .
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15-1
15-2
15-3
15-9
15-12
15-13
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16-2
16-2
16-2
16-3
17.1 ASCII Files . . . . . . . . . . . . . . . . . . . . . . .
17.1.1 Matrix Data . . . . . . . . . . . . . . . . . .
17.1.2 General File I/O . . . . . . . . . . . . . . .
17.2 Data Sets . . . . . . . . . . . . . . . . . . . . . . . .
17.2.1 Layout . . . . . . . . . . . . . . . . . . . .
17.2.2 Creating Data Sets . . . . . . . . . . . . .
17.2.3 Reading and Writing . . . . . . . . . . . . .
17.2.4 Distinguishing Character and Numeric Data
17.3 GAUSS Data Archives . . . . . . . . . . . . . . . . .
17.3.1 Creating and Writing Variables to GDA’s . .
17.3.2 Reading Variables from GDA’s . . . . . . .
17.3.3 Updating Variables in GDA’s . . . . . . . .
17.4 Matrix Files . . . . . . . . . . . . . . . . . . . . . . .
17.5 File Formats . . . . . . . . . . . . . . . . . . . . . .
17.5.1 Small Matrix v89 (Obsolete) . . . . . . . . .
17.5.2 Extended Matrix v89 (Obsolete) . . . . . .
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17-3
17-3
17-6
17-7
17-7
17-8
17-8
17-9
17-11
17-11
17-12
17-13
17-13
17-14
17-15
17-16
16 Compiler
16.1 Compiling Programs . . . . . .
16.1.1 Compiling a File . . .
16.2 Saving the Current Workspace
16.3 Debugging . . . . . . . . . . .
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17 File I/O
xii
Contents
17.5.3
Small String v89 (Obsolete) . . . . . . . . . . . . . . . . . . . . . . .
17-16
17.5.4
Extended String v89 (Obsolete) . . . . . . . . . . . . . . . . . . . . .
17-17
17.5.5
Small Data Set v89 (Obsolete) . . . . . . . . . . . . . . . . . . . . .
17-17
17.5.6
Extended Data Set v89 (Obsolete) . . . . . . . . . . . . . . . . . . .
17-19
17.5.7
Matrix v92 (Obsolete) . . . . . . . . . . . . . . . . . . . . . . . . . .
17-20
17.5.8
String v92 (Obsolete) . . . . . . . . . . . . . . . . . . . . . . . . . .
17-20
17.5.9
Data Set v92 (Obsolete) . . . . . . . . . . . . . . . . . . . . . . . . .
17-21
17.5.10 Matrix v96 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
17-22
17.5.11 Data Set v96 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
17-23
17.5.12 GAUSS Data Archive . . . . . . . . . . . . . . . . . . . . . . . . . .
17-24
18 Foreign Language Interface
18.1 Writing FLI Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
18-2
18.2 Creating Dynamic Libraries . . . . . . . . . . . . . . . . . . . . . . . . . . . .
18-3
19 Data Transformations
19.1 Data Loop Statements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
19-2
19.2 Using Other Statements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
19-3
19.3 Debugging Data Loops . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
19-3
19.3.1
Translation Phase . . . . . . . . . . . . . . . . . . . . . . . . . . . .
19-3
19.3.2
Compilation Phase
. . . . . . . . . . . . . . . . . . . . . . . . . . .
19-3
19.3.3
Execution Phase . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
19-4
19.4 Reserved Variables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
19-4
20 The GAUSS Profiler
20.1 Using the GAUSS Profiler . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
20-1
20.1.1
Collection
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20-1
20.1.2
Analysis . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
20-2
xiii
GAUSS User Guide
21 Publication Quality Graphics
21.1 General Design . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
21.2 Using Publication Quality Graphics . . . . . . . . . . . . . . . . . . . . . . .
21-1
21-2
21.2.1
Getting Started . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
21-2
21.2.2
Graphics Coordinate System . . . . . . . . . . . . . . . . . . . . . .
21-6
21.3 Graphic Panels . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
21-7
21.3.1
Tiled Graphic Panels
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21-7
21.3.2
Overlapping Graphic Panels
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21-7
21.3.3
Nontransparent Graphic Panels . . . . . . . . . . . . . . . . . . . . .
21-8
21.3.4
Transparent Graphic Panels . . . . . . . . . . . . . . . . . . . . . . .
21-8
21.3.5
Using Graphic Panel Functions . . . . . . . . . . . . . . . . . . . . .
21-8
21.3.6
Inch Units in Graphic Panels . . . . . . . . . . . . . . . . . . . . . .
21-10
21.3.7
Saving Graphic Panel Configurations . . . . . . . . . . . . . . . . . .
21-10
21.4 Graphics Text Elements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
21-10
21.4.1
Selecting Fonts . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
21-11
21.4.2
Greek and Mathematical Symbols . . . . . . . . . . . . . . . . . . .
21-12
21.5 Colors
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
21-14
21.6 Global Control Variables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
21-14
22 Graphics Editor
22.1 Introduction to the Graphics Editor . . . . . . . . . . . . . . . . . . . . . . . .
22.1.1
22-1
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
22-1
22.2 Graphics Editor Workspace . . . . . . . . . . . . . . . . . . . . . . . . . . . .
22-2
xiv
22.2.1
Toolbar . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
22-2
22.2.2
Status Bar . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
22-3
22.2.3
File menu commands . . . . . . . . . . . . . . . . . . . . . . . . . .
22-4
22.2.4
Edit menu commands . . . . . . . . . . . . . . . . . . . . . . . . . .
22-5
22.2.5
View menu commands . . . . . . . . . . . . . . . . . . . . . . . . .
22-5
22.2.6
Draw menu commands . . . . . . . . . . . . . . . . . . . . . . . . .
22-6
22.2.7
Export menu commands . . . . . . . . . . . . . . . . . . . . . . . .
22-7
22.2.8
Help menu commands
22-7
. . . . . . . . . . . . . . . . . . . . . . . . .
Contents
22.2.9
Object Action Context Menu
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22-7
22.2.10 Page Context Menu . . . . . . . . . . . . . . . . . . . . . . . . . . .
22-8
22.2.11 Setting the Page/View Properties . . . . . . . . . . . . . . . . . . . .
22-9
22.2.12 Setting the Pen/Fill Properties
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22-10
22.2.13 Graphical Objects . . . . . . . . . . . . . . . . . . . . . . . . . . . .
22-11
22.2.14 Modifying the Graphical Objects . . . . . . . . . . . . . . . . . . . .
22-14
22.3 File Management . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
22-16
22.3.1
Exporting Files . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
22-16
23 Time and Date
23.1 Time and Date Formats . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
23-2
23.2 Time and Date Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
23-4
23.2.1
Timed Iterations . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
23-6
24.1 Command Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
24-1
24.2 Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
24-3
24.3 Examples . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
24-12
24.4 Error Messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
24-15
24 ATOG
25 Error Messages
26 Maximizing Performance
26.1 Library System . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
26-1
26.2 Loops . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
26-2
26.3 Memory Usage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
26-3
26.3.1
Hard Disk Maintenance . . . . . . . . . . . . . . . . . . . . . . . . .
26-4
26.3.2
CPU Cache . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
26-4
xv
GAUSS User Guide
A Fonts
A.1
A.2
A.3
A.4
Simplex .
Simgrma
Microb .
Complex
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A-2
A-3
A-4
A-5
Reading and Setting the Tolerance . . . . . . . . . . . . . . . . . . . . . . . .
Determining Singularity . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
C-2
C-2
B Reserved Words Appendix
C Singularity Tolerance Appendix
C.1
C.2
27 Command Reference Introduction
27.1
27.2
27.3
27.4
Documentation Conventions . . . . .
Command Components . . . . . . . .
Using This Manual . . . . . . . . . . .
Global Control Variables . . . . . . . .
27.4.1 Changing the Default Values
27.4.2 The Procedure gausset . . .
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27-2
27-3
27-4
27-5
27-5
27-6
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28-1
28-23
28-24
28-29
28-30
28-32
28-33
28-42
28-43
28 Commands by Category
28.1
28.2
28.3
28.4
28.5
28.6
28.7
28.8
28.9
xvi
Mathematical Functions . . . .
Finance Functions . . . . . . .
Matrix Manipulation . . . . . .
Sparse Matrix Handling . . . .
N-Dimensional Array Handling
Structures . . . . . . . . . . .
Data Handling (I/0) . . . . . . .
Compiler Control . . . . . . . .
Multi-Threading . . . . . . . .
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Contents
28.10 Program Control . . . . . . . . . . .
28.11 OS Functions and File Management
28.12 Workspace Management . . . . . .
28.13 Error Handling and Debugging . . .
28.14 String Handling . . . . . . . . . . . .
28.15 Time and Date Functions . . . . . .
28.16 Console I/O . . . . . . . . . . . . .
28.17 Output Functions . . . . . . . . . . .
28.18 Graphics . . . . . . . . . . . . . . .
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28-44
28-49
28-50
28-50
28-51
28-53
28-55
28-56
28-57
29 Command Reference
D Obsolete Commands
E Colors
Index
xvii
List of Figures
List of Figures
3.1
3.2
3.3
3.4
3.5
3.6
3.7
3.8
3.9
3.10
3.11
3.12
3.13
3.14
3.15
3.16
3.17
3.18
12.1
22.1
22.2
22.3
Command Page . . . . . . . . . . . .
Command Page Toolbar . . . . . . .
Working Directory Toolbar . . . . . .
Command History Toolbar . . . . . .
Run, Debug, and Edit Buttons . . . .
Command Page Widgets . . . . . . .
Command History Window . . . . . .
Source Page . . . . . . . . . . . . . .
Programming Editor . . . . . . . . . .
Find and Replace . . . . . . . . . . .
Find and Replace Regular Expression
Data Page . . . . . . . . . . . . . . .
Data Page Toolbar . . . . . . . . . . .
The Struct Editor . . . . . . . . . . .
Debug Toolbar . . . . . . . . . . . . .
Debug Window . . . . . . . . . . . .
Watch Window . . . . . . . . . . . . .
Help Page . . . . . . . . . . . . . . .
Structure tree for e1 . . . . . . . . . .
Graphics Editor Workspace . . . . . .
Graphics Editor Toolbar . . . . . . . .
Graphics Editor Status Bar . . . . . .
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3-2
3-4
3-5
3-5
3-6
3-7
3-8
3-11
3-11
3-14
3-15
3-17
3-18
3-19
3-21
3-22
3-24
3-26
12-7
22-2
22-3
22-3
xix
Introduction
Introduction
1.1
1
Product Overview
TM
GAUSS is a complete analysis environment suitable for performing quick calculations, complex
analysis of millions of data points, or anything in between. Whether you are new to computerized
analysis or a seasoned programmer, the GAUSS family of products combine to offer you an easy
to learn environment that is powerful and versatile enough for virtually any numerical task.
Since its introduction in 1984, GAUSS has been the standard for serious number crunching and
complex modeling of large-scale data. Worldwide acceptance and use in government, industry,
and the academic community is a firm testament to its power and versatility.
The GAUSS System can be described several ways: It is an exceptionally efficient number
cruncher, a comprehensive programming language, and an interactive analysis environment.
GAUSS may be the only numerical tool you will ever need.
1-1
GAUSS User Guide
1.2
Documentation Conventions
The following table describes how text formatting is used to identify GAUSS programming
elements:
1-2
Text Style
Use
Example
regular text
narrative
“... text formatting is used ...”
bold text
emphasis
“...not supported under UNIX.”
italic text
variables
“... If vnames is a string or has
fewer elements than x has
columns, it will be ...”
monospace
code example
if scalerr(cm);
cm = inv(x);
endif;
monospace
filename, path, etc.
“...is located in the examples
subdirectory...”
monospace
bold
reference to a GAUSS
command or other
programming element
within a narrative
paragraph
“...as explained under create...”
S C
reference to section of
the manual
“...see O P,
Section 7.7...”
2.1
2
Installation Under UNIX/Linux
1. Make a directory to install GAUSS in.
2. cd to that directory.
3. Gunzip the .gz file if there is one.
4. Untar the .tar file.
5. Run the executable script ginstall.
6. Put the installation directory in the executable path.
7. Put the installation directory in the shared library search path.
8. Install the license. (To receive a license and license installation instructions, email
[email protected].)
For last-minute information, see README.term.
2-1
Getting
Started
Getting Started
GAUSS User Guide
2.2
2.2.1
Installation Under Windows
Machine Requirements
• A Pentium or AMD computer or equivalent.
• Operating System and Memory (RAM) requirements:
– Windows XP, 256 MB minimum, 512 MB recommended.
– Windows Vista 32-bit, 512 MB minimum, 1 GB recommended.
– Windows Vista 64-bit, 1 GB minimum, 2 GB or more recommended.
– Windows 7 32-bit, 1 GB minimum, 2 GB or more recommended.
– Windows 7 64-bit, 2 GB minimum, 3 GB or more recommended.
• Minimum of 100 MB free hard disk space, more may be needed depending on the size of
matrices and the complexity of the program.
• Monthly defragmenting is recommended.
2.2.2
Installation from Download
For download instructions, email [email protected].
2.2.3
Installation from CD
Insert the GAUSS compact disc into the CD-ROM drive, and setup should start automatically. If
setup does not start automatically, click Start, then click Run. Type D:\setup.exe in the dialog
box (where D is the drive letter of the CD-ROM drive).
You can use this procedure for the initial installation of GAUSS, and for additions or
modifications to GAUSS components.
To receive a license and license installation instructions, email [email protected].
2-2
Introduction to the GAUSS
Graphical User Interface
Page Organization Concept
The GAUSS graphical user interface is organized into separate “pages.” Pages are separate,
customizable, main windows with their own set of widgets. Each page is designed to facilitate the
performance of one of the common tasks performed in GAUSS: entering commands interactively,
editing a program, examining data, debugging a program, and accessing the help system. Each
page is a tab on the main application, allowing you to instantly access a window custom
configured for the task you wish to perform. The GAUSS graphical user interface is composed of
five different pages.
Command Page
For executing interactive commands.
Source Page
For editing program files.
Data Page
For examining and editing GAUSS matrices and other data.
Debug Page
For interactively debugging your programs.
Help Page
For accessing the GAUSS HTML help system.
3-1
GUI Intro
3.1
3
GAUSS User Guide
Each page may be undocked and from the main application and redocked by toggling the Dock
button on the right side of the status bar. Navigation between undocked pages may be
accomplished with ALT+TAB and ALT+SHIFT+TAB. To navigate between docked pages, use
CTRL+TAB to cycle forward and CTRL+SHIFT+TAB to cycle backwards between pages.
Each page has its own toolbars and menus. The menus and toolbars facilitate intuitive navigation
through the GUI as well as performing desired functions. For example, clicking the New toolbar
from any page in the GUI will bring the Source Page to the top of the window stack with a new file
opened ready for editing. More details on navigating the GUI are in Section 4, N 
GAUSS G U I.
3.2
Command Page
The Command Page is for entering interactive commands to GAUSS.
Figure 3.1: Command Page
3-2
Introduction to the GAUSS Graphical User Interface
3.2.1
Menus and Toolbars
Command Page
File Menu
Tools Menu
Creates a new, untitled file in a programming editor on the
Source Page.
Open
Opens an existing file in a programming editor on the
Source Page.
Print
Prints selected text.
Print Setup
Specifies the printer to use and other options such as paper
tray and page orientation.
Recent Files
Holds a selectable dropdown list of recently edited files.
Exit
Exits a GAUSS session.
Undo
Restores your last unsaved change.
Redo
Re-inserts changes removed with undo.
Cut
Removes selected text and copies it to the clipboard.
Copy
Copies selected text to the clipboard.
Paste
Copies the clipboard contents to the cursor position.
Preferences
Allows you to configure the GAUSS user environment.
Change Font
Allows you to specify a new font. Aptech recommends
using a monospaced font such as Courier.
Change Working
Directory
Allows you to browse for a new working directory.
Clear Working
Directory History
Deletes the contents of your working directory history.
Recent Working
Directories
Contains a dropdown list of your most recent working
directories.
View Menu
The View menu lets you toggle on or off the windows on the current page.
Help Menu
Goto Help
Takes you to the Help Page.
About GAUSS
Provides information regarding your version of GAUSS.
3-3
GUI Intro
Edit Menu
New
GAUSS User Guide
New Print
Open
Copy
Cut
Paste
Figure 3.2: Command Page Toolbar
3.2.2
Command Page Toolbar
New
Opens a new, untitled document in a programming editor on the Source Page
and brings you to the Source Page.
Open
Opens an existing file for editing.
Cut
Removes selected text and places it on the clipboard.
Copy
Copies selected text to the clipboard.
Paste
Copies the clipboard contents to the cursor position.
Print
Prints selected text.
Run
Runs the file at the top of the Action List.
Debug
Debugs the file at the top of the Action List.
Edit
Opens the file at the top of the Action List.
Stop Program
Stops a running GAUSS program.
3.2.3
Working Directory Toolbar
The Working Directory Toolbar contains a dropdown list that shows your current working
directory and a history of recent directories. The Change Working Directory button allows you to
browse for and select a new working directory.
3-4
Introduction to the GAUSS Graphical User Interface
Current
Working
Directory
Change
Working
Directory
3.2.4
GUI Intro
Figure 3.3: Working Directory Toolbar
Command History Toolbar
Search
Run Previous
Paste Search
Next
Figure 3.4: Command History Toolbar
Run
Executes the highlighted command from the command history.
Paste
Pastes the highlighted command to the Command Input Window for further
editing.
Search Previous
Searches the Command Output Window for previous executions of a
command and its output.
Search Next
Searches the Command Output Window for the next execution of a
command and its output.
3-5
GAUSS User Guide
3.2.5
The Run, Debug, and Edit Buttons
Run
Debug
Edit
Stop
Figure 3.5: Run, Debug, and Edit Buttons
Immediately to the right of the Run, Debug, and Edit buttons is a downward pointing triangle.
Clicking on this triangle reveals the Action List. The Action List is a selectable drop down list of
your most recently acted upon files. The Run, Debug, and Edit buttons share the same Action List.
You may add a file to the Action List by running it from the command line or while editing a file,
click on the drop down menu from Run, Debug, or Edit, and select Current File. Clicking on the
Run button will run the file on the top of the Action List. Placing your mouse over the Run Button
produces a tooltip indicating which file will be run.
To run one of the other files in the list, access the Action List by clicking on the triangle next to the
Run button and select the name of the file you wish to run. The Debug and Edit buttons work in
the same manner.
3.3
Layout
The Command Page contains four widgets: the Program Output Window, the Command History
Window, the Command Input Window, and the Error Output Window.
The Command Output Window shows the output from interactive commands and programs. It is
also the location for user input requested by the GAUSS functions keyw and cons.
3-6
Introduction to the GAUSS Graphical User Interface
Program Output Window
Command
History
Window
Error Output
Window
GUI Intro
Command Input
Window
Figure 3.6: Command Page Widgets
3.3.1
Command History Window
The Command History Window contains a list of recently executed commands. Commands in the
command history can be executed by double clicking them or highlighting a command and
clicking the Run button from the Command History toolbar.
Commands can be sent to the Command Input Window for further editing before executing by
highlighting a command and clicking the Paste button. The Search Next and Search Previous
buttons will search the Command Output Window forward or backwards for previous executions
of that command so that you may inspect its output.
To remove commands from the command history, right-click over a command and select Delete to
remove only the highlighted command or Delete All to remove the entire contents of the
command history.
3-7
GAUSS User Guide
Search
Run Previous
Paste Search
Next
Figure 3.7: Command History Window
3.3.2
The Command Input Window
The Command Input Window is where you enter interactive commands in GAUSS. The
Command Input Window provides a command history with fully featured command line editing.
3.4
Command Line History and Command Line Editing
When you run a command at the GAUSS prompt, it is added to your command line history. The
last 1,000 commands executed at the GAUSS command line are stored. The following keystrokes
are supported for movement and editing at the command line and for retrieving the command line
history:
3.4.1
Movement
Left Arrow or
CTRL+B
3-8
Moves cursor left one character.
Introduction to the GAUSS Graphical User Interface
Moves cursor right one character.
HOME
Moves cursor to beginning of line.
END or CTRL+E
Moves cursor to end of line.
ALT+Left Arrow or
CTRL+Left Arrow
Moves cursor left one word.
ALT+Right Arrow or
CTRL+Right Arrow
Moves cursor right one word.
Up Arrow
Search up through command history.
Down Arrow
Search down through command history.
GUI Intro
3.4.2
Right Arrow or
CTRL+F
Error Output Window
The Error Output Window shows errors messages from program runs or interactive commands. It
may be viewed from any page by clicking the Error Output button on the right side of the status
bar.
3.5
Source Page: Editing Programs
The Source Page is for creating and editing programs and procedures.
3.5.1
Menus and Toolbars
Section 3.2 provides details of the main menus and toolbars. The Source Page contains the
following additional menu options.
3-9
GAUSS User Guide
File Menu
Save
Saves the active file.
Save As
Saves the active file with a new or different file or path name.
Close
Closes the selected file.
Close All
Closes all open files.
Window Menu
Split
Horizontally
Tiles any open programming editors horizontally.
Split
Vertically
Tiles any open programming editors vertically.
Remove Split
Removes any editor window tiling.
Close
Closes the selected file.
Close All
Closes all open files.
3.5.2
Layout and Usage
The Source Page contains four separate window components.
Programming Editor
Individual programming editors are opened in the editor docking area. The editor docking area
allows tabbing of multiple open files, with the option to tile editors with a horizontal or vertical
split. Select Window->Split Horizontally or Window->Split Vertically to tile open editor
windows.
3-10
Introduction to the GAUSS Graphical User Interface
GUI Intro
Figure 3.8: Source Page
Figure 3.9: Programming Editor
3-11
GAUSS User Guide
Individual editor windows can be pulled out of the Source Page by grabbing their banner and
dragging them to the desired location.
Programming editor features:
1. Syntax highlighting: The GAUSS programming editor will provide syntax highlighting for
GAUSS, C/C++, Java, Fortran, R and many other languages.
2. Autocompletion: Autocompletion is available in the GAUSS programming editor for
GAUSS functions.
Using autocomplete: if the characters you enter match items in the autocomplete list, a
dropdown box will appear containing those functions. To navigate the dropdown list, press
the down arrow or continue typing until only one selection remains. Once the desired
command is highlighted, press the ENTER key to insert the remainder of the word.
3. Tooltips: After a GAUSS command and an opening parenthesis has been entered, a tooltip
will appear with the argument list for the function.
4. Code folding: At the start of code blocks (e.g., procedure definitions, do and for loops, and
if statements), the left margin of the programming editor will contain a +. Clicking the +
will hide the block of code from view and place a horizontal line across the editor indicating
folded code and changing the + to a -. Clicking on the - will reveal the hidden code.
5. Autoindenting: The GAUSS programming editor provides automatic code indenting and
deindenting. Autoindenting not only simplifies the process of writing code but also
encourages the creation of readable code.
Programming Editor Hot Keys
3-12
Introduction to the GAUSS Graphical User Interface
Select All.
CTRL+C
Copy.
CTRL+D
Debug current file.
CTRL+F
Find and replace.
CTRL+G
Go to Line.
CTRL+L
Delete line.
CTRL+N
Open new file.
CTRL+O
Open existing file.
CTRL+P
Print file.
CTRL+Q
Used for block commenting.
CTRL+R
Run current file.
CTRL+S
Save current file.
CTRL+T
Switches current line with the line above.
CTRL+V
Paste.
CTRL+W
Closes the current file.
CTRL+Z
Undo.
CTRL+Y
Redo.
CTRL+˜
Cycles through open editor windows.
GUI Intro
CTRL+A
3-13
GAUSS User Guide
3.5.3
Find and Replace
From the Edit Menu, selecting Find and Replace or pressing CTRL+F will bring up the find and
replace widget at the bottom of your open programming editor. If a word is highlighted when you
access find and replace, it will automatically be present in the find box when the find and replace
widget is opened. Press the ENTER key or > to search forward. Press the < key to search
backwards. To close the find and replace widget, press ESC or click the x button on the left.
Search Search
Backward Forward
Exit
Search/Replace
Replace
Backward
Highlighted
Search/Replace
Forward
Figure 3.10: Find and Replace
The Replace Box has three buttons: > means replace the highlighted expression and search
forwards, < means replace the highlighted expression and search backwards and ∨ means replace
the highlighted text and do not change the cursor position.
Regular Expressions
Find and Replace in GAUSS supports regular expression searching. Regular expression searching
gives users tremendous power allowing quick and precise search and replace throughout an entire
file. For example, let us start with a file containing the following commands:
r = 100;
c = 50;
x = rndn(r,c);
y = rndu(r,c);
z = x.*rndn(r,c);
3-14
Introduction to the GAUSS Graphical User Interface
Regular expressions allow you to perform very specific find and replace commands. Suppose that
we want to find all usages o f rndu and rndn and replace them with rndKMu.
GUI Intro
Figure 3.11: Find and Replace Regular Expression
To open Find and Replace, we enter CTRL+F in out open text editor. In the Find and Replace
widget, select the check box next to Regex to enable regular expression searching. One of the
most simple regular expression options is to add a ’.’. The ’.’ means any character. So, if we
search for “rnd.” that will find any string that contains rnd followed by any character, such as
rnda, rndb, rndc, rndn, rndu, etc. Now enter “rndKMu” in the replace box and click Replace
All. Now all instances of rndu and rndn should be replaced with rndKMu.
3.5.4
Changing Editor Properties
Programming editor preferences can be accessed by selecting: Tools->Preferences from the menu
bar. From the Preferences window, select Source from the tree on the left. Here you can
3-15
GAUSS User Guide
customize the programming editor’s behavior.
3.5.5
Command Input Window
The Command Input Window can be accessed by toggling the Input button on the right side of the
status bar. For details regarding the features and usage of the Command Input Window, see
Section 3.3.2.
3.5.6
Error Output Window
The Error Output Window can be accessed by toggling the Error Output button on the right side of
the status bar. For details regarding the features and usage of the Error Output Window, see
Section 3.4.2.
3.6
Data Page
Section 3.2.1 provides details of the main menus and toolbars. The Data Page contains the
following changes to the toolbar and menu options.
3.6.1
Menu Bar
Symbol Editor Menu
Edit Symbol
Opens an active symbol from your current GAUSS workspace in a symbol
editor.
Save Symbol
Saves changes to the symbol in the active symbol editor.
Reload
Reloads a symbol that is out-of-sync with the GAUSS symbol table.
Symbol
Note: This only applies if auto-reload mode is turned off.
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Introduction to the GAUSS Graphical User Interface
GUI Intro
Figure 3.12: Data Page
Toggle
Turns on/off autoreload for the active symbol editor.
Auto-reload
Preferences
Brings up preference dialog for changing the settings of open symbol editors.
Window Menu
Split
Tiles open symbol editors horizontally.
Horizontally
Split
Tiles open symbol editors vertically.
Vertically
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GAUSS User Guide
Edit
Reload
Symbol Symbol
Save
Symbol
Figure 3.13: Data Page Toolbar
Toolbar
New
Opens an active symbol from your current GAUSS workspace in a symbol
editor.
Save
Saves changes to the symbol in the active symbol editor.
Reload
Reloads an out-of-sync symbol editor. Note: This applies only if autoreload
is disabled.
3.6.2
Layout
The Data Page has two main widgets: the symbol tree and the source editor docking area. The
Command Input and Error Windows are also accessible from the toggle buttons on the right side
of the status bar.
The Symbol Tree window lists all of your active symbols, organized by type. To view your active
symbols, click on the node expander or right click and select Symbol View from the context
menu. Hovering over a symbol in the Symbol Tree will produce a tooltip with a preview of the
symbol’s contents. To view the entire contents of a symbol, double-click the symbol or right-click
the symbol and select Edit. The symbol will now appear in a symbol editor (see Section 3.6.3,
Symbol Editor).
Double-clicking an already open symbol will bring that symbol to the top of the stack of open
symbol editors. If you would like to open a second copy of a symbol, right-click on the symbol in
the symbol tree and select Edit Another Copy. GAUSS allows you to open more than one copy
of each symbol so that you can examine different portions of a large matrix at the same time.
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Introduction to the GAUSS Graphical User Interface
Special Case: Structures
To view a structure in the GAUSS Symbol Editor, click the + next to the Structures node on the
Symbol Tree. From here you will see a full list of all structures in your current GAUSS
workspace. Clicking the + next to an individual structure will reveal all members of a structure.
To view the contents of any member of a GAUSS structure, first open the structure in a Struct
Viewer, by either double-clicking or right-clicking and selecting Edit over the name of the
structure in the Symbol Tree. Once open in the Struct Viewer, individual members of the structure
can be accessed for viewing and editing from the Struct Tree.
GUI Intro
The Struct Editor
When opened from the Symbol Tree, structures will be loaded into a special Struct Editor. The
Struct Editor is composed of a Struct Tree Widget and a Struct Member Editor. The Struct Tree
Widget displays the structure being edited and its members names, data types and dimensions.
The Struct Member editor displays the contents of individual struct members. The Struct Editor is
displayed in the Source Editor docking area like all other Source Editors.
Figure 3.14: The Struct Editor
Individual structure members can be opened for editing or viewing from the Struct Tree Widget in
the same manner as other data types, such as matrices, are opened from the Symbol Tree.
Structure members will be opened in a Symbol Editor to the right of the Struct Tree Widget.
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GAUSS User Guide
3.6.3
Symbol Editor
Symbol editors are like spreadsheets that allow viewing and editing data in your workspace. Data
may be viewed in decimal, scientific, hexadecimal, or character representation. Double-clicking in
a cell allows you to change its contents. Navigation throughout the cells can be accomplished with
the arrow keys, tab, and the mouse.
To highlight multiple cells, click on the corresponding row or column header. To highlight the
entire contents of a symbol editory, click in the empty header box that connects the first row
header to the first column header.
Autoreload
By default, open symbol editors will automatically update when the symbol has been changed
programmatically. This behavior is referred to as autoreload. A symbol editor in autoreload mode
will show (auto) on its header. The header will also display (sync), indicating that the symbol
editor’s contents are synchronized with the current value of the symbol in the GAUSS symbol
table.
If you would like the contents of a particular symbol editor to stay the same even if the value of
the symbol is changed by running a program or an interactive command, you may disable
autoreload for that symbol. If the value of a symbol with autoreload disabled is changed in the
GAUSS symbol table, the symbol editor will display the message out-of-sync. This indicates
that the values in the symbol editor are not current.
3.7
3.7.1
Debug Page
Menus and Toolbars
Go
Runs the program to the next breakpoint.
Stop
Terminates a debugging session.
Toggle
Sets/Clears a breakpoint at the cursor.
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Introduction to the GAUSS Graphical User Interface
Breakpoint
Clear
Clears all breakpoints in a file.
Breakpoints
Opens a watch variable in a symbol editor.
Step Into
Runs the next executable line of code in the application and steps into
procedures.
Step Over
Runs the next executable line of code, but does not step into procedures.
Step Out
Runs the remainder of the current procedure and stops at the next line in the
calling procedure.
Run to Cursor
Runs the program until it reaches the cursor position.
Toggle
Set
Go Breakpoint Watch
Stop
Step
Over
Clear
Step
Breakpoint Into
Run to
Cursor
Step
Out
Figure 3.15: Debug Toolbar
Components and Usage
The Debug Page is composed of two windows, the Breakpoint List and the Debug Window. The
Debug Window is a programming editor window specifically configured for debugging programs.
The Debug Window indicates which line it is on by the >>> located in the left margin. This is also
the location where breakpoints are added. To add a breakpoint, click in the left margin of the
Debug Window on the line you wish to add the breakpoint. Clicking an active breakpoint will
remove it.
3-21
GUI Intro
Set Watch
GAUSS User Guide
Figure 3.16: Debug Window
Starting and Stopping the Debugger
You can start debugging of a file you are in by pressing CTRL+D. Click the Debug button to
debug the file in the top of the Action List. Placing your mouse over the Debug button will reveal a
tooltip with the name of this file, or click the downward pointing triangle next to the debug button
and select a file from the list.
When the debugger is started, it will highlight the first line of code to be run. Any breakpoints are
shown in the left margin of the window. You can stop debugging at any time by clicking the Stop
button on the debug toolbar.
3.7.2
Using Breakpoints
Breakpoints stop code execution where you have inserted them. Breakpoints are normally set prior
to running the debugger, but can also be set or cleared during debugging by clicking the Set/Clear
Breakpoint command on the Debug menu.
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Introduction to the GAUSS Graphical User Interface
3.7.3
Setting and Clearing Breakpoints
To set breakpoints in any part of the file not currently being executed, just click in the left margin
of the line on which you would like the breakpoint. Alternatively, you can highlight a line then
click Toggle Breakpoint.
To clear a breakpoint in the file, click on the breakpoint you would like to remove or click a line of
code that has a breakpoint set and then click Set/Clear Breakpoint. You can clear all breakpoints
from the active file by clicking Clear All Breakpoints.
GUI Intro
3.7.4
Stepping Through a Program
GAUSS’s debugger includes the ability to step into, step out of, and step over code during
debugging.
Use Step Into to execute the line of code currently highlighted by the debugger.
Use Step Out to execute to the end of the current function without pause and return to the calling
function.
Use Step Over to execute the line of code currently highlighted by the debugger without entering
the functions that are called.
3.7.5
Viewing and Editing Variables
GAUSS allows you to view and edit the values of variables during debugging.
Viewing Variable Values During Debugging
Once the debugger is started, the editor window uses floatover variable windows for viewing
variable data. Floatover variable windows give a quick view of the value a variable currently holds
by simply moving your mouse over the variable name in the edit window.
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GAUSS User Guide
The floatover variable window is only intended to give a quick view of the data, so it may not
show all data held by the variable. If you need to view more data, click on the variable name and
type CTRL+E or click the Set Watch Variable and enter the variable name.
Editing Variable Values During Debugging
The debugger integrates the Matrix Editor to edit values of loaded variables, or to use as a watch
window to view the changing values of variables as you step through a program.
To edit a variable value, highlight the variable in the edit window, or the Command Input Window
and then open the Matrix Editor. You can use the menu or toolbar to start the Matrix Editor.
Making a Watch Window
You can make the Matrix Editor a Watch Window, allowing you to watch the changing value of a
variable as the lines of the program are executed. You can activate the Watch Window by clicking
Set Watch on the Debug toolbar or by highlighting a variable name in the Debugger Window and
pressing CTRL+W.
Figure 3.17: Watch Window
You use a Watch Window to see how variables change in value during debugging. Watch variables
can be specified prior to running the debugger or during a debugging session.
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Introduction to the GAUSS Graphical User Interface
The debugger searches for a watch variable using the following order:
1. A local variable within a currently active procedure.
2. A global variable.
A watch variable can be the name of a matrix, a scalar, a string array, or a string. For a matrix or a
string array, the first element is displayed. If a matrix element is clicked, the Matrix Editor is
loaded with the matrix. The matrix elements can be changed during the debugging session.
GUI Intro
3.8
Help Page
The Help Page gives you access to the entire GAUSS help system in HTML format. The table of
contents tree is on the left. Click the + symbol to expand a particular section of the contents and
double-click on the title to view the page. As on the other pages, the Command Input Window and
the Error Window are available via toggle buttons on the status bar. It can be helpful to enter an
interactive command and/or view error output while simultaneously viewing the relevant
documentation.
3.8.1
Hot Keys
F1
Opens the Command Reference section for the highlighted
command.
CTRL+F1
Opens a programming editor with the function definition
of a highlighted procedure.
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GAUSS User Guide
Figure 3.18: Help Page
3-26
Navigating the GAUSS Graphical
User Interface
4
Navigating
the GUI
Navigation of the GAUSS Graphical User Interface is designed to naturally follow your actions.
For example, if the action you would like to perform is debugging the file that you are editing, you
can either enter CTRL+D to debug or select the file from the Debug Toolbar Button’s drop down
Action List. Both of these options will begin your debugging session and take you to the Debug
Page. Regardless of the method you choose to initiate the action, debugging in this case, the
navigation is done for you.
The same automatic and intuitive navigation is enabled for many common GAUSS actions, such
as opening a new or existing file for editing or using the F1 help.
Since GAUSS program output can be viewed in many ways such as symbol editors on the Data
Page or graphic files, running a program or executing a command does not automatically navigate
to the Command Page. However, if the Program Output Window from the Command Page is your
modality of choice, the option to automatically navigate to the Command Page can be selected as
an option under Tools->Preferences.
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GAUSS User Guide
4.1
Hot Keys and Shortcuts
F5
Run file at top of Action List.
F6
Debug file at top of Action List. Inside a debug session,
F6 will cause the debugger to run to the next breakpoint,
or the end of the file if no breakpoint is set.
F7
Edit file at top of Action List.
F8
Step in (During a debug session).
F9
Step over (During a debug session).
F10
Step out (During a debug session).
The Control Keys operate on a file that is being edited or is open in a Programming Editor and has
focus. This file is referred to as the Active File.
4.2
4-2
CTRL+R
Run the Active File.
CTRL+D
Debug the Active File.
Navigating Between Pages
CTRL+1
Brings up the Command Page.
CTRL+2
Brings up the Source Page.
CTRL+3
Brings up the Data Page.
CTRL+4
Brings up the Debug Page.
Navigating the GAUSS Graphical User Interface
Brings up the Help Page.
CTRL+TAB
Brings up the next page. For example, CTRL+TAB
from the Command Page will bring up the Source Page.
CTRL+TAB from the Help Page will wrap and bring up
the Command Page.
ALT+TAB
Cycles between any pages that are undocked as well as
other open programs.
WINDOW+TAB
Windows only: Cycles between any pages that are undocked as well as other open programs.
Mouse Scroll Wheel
When floating over any set of tabs, the mouse scroll wheel
will cycle through the open tabs. This will work for programming editor tabs, symbol editor tabs, and the main
page tabs on the left of the main application.
Navigating
the GUI
4.3
CTRL+5
Switch To Command Page on I/O
Under the Tools->Preferences->Command is a check box entitled Switch to Command Page on
I/O. Selecting this option will bring you to the command page if any program output is printed to
the Program Output Window, or if any input is requested by GAUSS functions key, keyw or cons.
4.4
Viewing Program Output from Other Pages
The Program Output Window may be pulled out of the Command Page by selecting the Program
Output banner and dragging it. The Program Output Window may then be placed and resized. The
Program Output Window will remain in place and on the top of the window stack, allowing you to
navigate freely between any other pages while continuing to observe the program output.
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GAUSS User Guide
4.5
F1 Help
If your cursor is on the name of a GAUSS command in an editor, you can press F1 and it will take
you to the Command Reference listing for that command. Inside the Help system, highlight
command names by double-clicking them to enable F1 help navigation.
4.6
CTRL+F1 Source Browsing
For procedures that reside in a GAUSS Library (.lcg file), you can browse to the procedure
definition and to the initiation of any global variables with CTRL+F1. Like F1 help, set your
cursor on the procedure or global variable name and enter CTRL+F1. If it resides in an active
library, the source file will be immediately opened in a Programming Editor.
To learn more about creating a User Library for your procedures, see Chapter 15.
4-4
Using the Command Line
Interface
5
TGAUSS is the command line version of GAUSS. The executable file, tgauss is located in the
GAUSS installation directory.
The format for using TGAUSS is:
tgauss flag(s) program program...
Execute file in batch mode and then exit. You can execute multiple files by
separating file names with spaces.
-l logfile
Set the name of the batch mode log file when using the -b argument. The
default is tmp/gauss.log###, where ### is the process ID.
Command
Line
-b
-e expression Execute a GAUSS expression. This command is not logged when GAUSS is in
batch mode.
-o
Suppress the sign-on banner (output only).
-T
Turn the dataloop translator on.
-t
Turn the dataloop translator off.
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GAUSS User Guide
5.1
Viewing Graphics
GAUSS generates .tkf files for graphical output. The default output for graphics is
graphic.tkf. On Windows, you can use vwr.exe to view the graphics file; on
UNIX/Linux/Mac, you can use vwrmp. Two functions are available to convert .tkf files to
PostScript for printing and viewing with external viewers: the tkf2ps function will convert .tkf
files to PostScript (.ps) files, and the tkf2eps function will convert .tkf files to encapsulated
PostScript (.eps) files. For example, to convert the file graphic.tkf to a postscript file named
graphic.ps use:
ret = tkf2ps(‘‘filename.tkf ’’, ‘‘filename.ps’’)
If the function is successful it returns 0.
5.2
Command Line History and Command Line Editing
When you run a command at the TGAUSS prompt, it is added to your command line history,
which is stored in a file called .gauss_prompt_history in your $(HOME) directory on
UNIX/Linux or in your $(HOMEDRIVE)\$(HOMEPATH) directory on Windows. A separate history
for commands entered in the command line debugger is stored in a file called
.gauss_debug_prompt_history in the same directory. By default, the last 500 commands
executed at the TGAUSS and debugger command lines are stored in these files. You can change
this number by changing prompt_hist_num in your gauss.cfg file. The following keystrokes
are supported for movement and editing at the command line and for retrieving the command line
history:
5.2.1
5-2
Movement
Left Arrow or CTRL+B
Moves cursor left one character
Right Arrow or CTRL+F
Moves cursor right one character
Using the Command Line Interface
5.2.2
Moves cursor to beginning of line
END or CTRL+E
Moves cursor to end of line
ALT+Left Arrow or
CTRL+Left Arrow
Moves cursor left one word
ALT+Right Arrow or
CTRL+Right Arrow
Moves cursor right one word
Editing
DELETE OR CTRL+D
Deletes character at cursor
BACKSPACE or CTRL+H
Deletes character left of cursor
CTRL+U
Cuts all characters left of cursor
CTRL+K
Cuts all characters right of cursor, including cursor
CTRL+X
Cuts whole line
ESC (Win only)
Deletes whole line
CTRL+V
Pastes text from buffer to left of cursor
CTRL+T
Transposes character at cursor and character left of
cursor
Command
Line
5.2.3
HOME or CTRL+A
History Retrieval
Up Arrow or CTRL+P
Retrieves previous line in history
Down Arrow or CTRL+P
Retrieves next line in history
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GAUSS User Guide
PAGE UP or CTRL+W
PAGE
DOWN
CTRL+S
Retrieves previous line in history that matches text to left
of cursor
or
Retrieves next line in history that matches text to left of
cursor
ALT+H or
OPTION+H (MAC only)
Prints prompt history to screen
!!
Runs last line in history
!num
Runs the num line in history
!-num
Runs the line num before current line in history;
!-1 is equivalent to !!
!text
Runs last line in history beginning with text
ALT+/ or ALT+? or
OPTION+/ (MAC only)
Prints help screen
Note that some of these keystrokes are mapped differently on different computers. For example,
on some computers, SHIFT+RIGHT ARROW behaves the same as RIGHT ARROW, while
ALT+RIGHT ARROW moves the cursor right one word. Therefore, multiple keystroke mappings
have been supported to maximize the availability of these commands on any given machine.
5.3
5.3.1
Interactive Commands
quit
The quit command will exit TGAUSS.
The format for quit is:
5-4
Using the Command Line Interface
quit
You can also use the system command to exit TGAUSS from either the command line or a
program (see system in the GAUSS L R).
The format for system is:
system
5.3.2
ed
The ed command will open an input file in an external text editor (see ed in the GAUSS L
R).
The format for ed is:
ed filename
5.3.3
browse
The format for browse is:
browse symbol
5.3.4
config
The config command gives you access to the configuration menu allowing you to change the way
GAUSS runs and compiles files.
5-5
Command
Line
The browse command allows you to search for specific symbols in a file and open the file in the
default editor. You can use wildcards to extend search capabilities of the browse command.
GAUSS User Guide
The format for config is:
config
Run Menu
Translator
Toggles on/off the translation of a file using dataloop. The translator
is not necessary for GAUSS program files not using dataloop.
Translator line
number tracking
Toggles on/off execution time line number tracking of the original
file before translation.
Line number
tracking
Toggles on/off the execution time line number tracking. If the
translator is on, the line numbers refer to the translated file.
Compile Menu
5-6
Autoload
Toggles on/off the autoloader.
Autodelete
Toggles on/off autodelete.
GAUSS Library
Toggles on/off the GAUSS library functions.
User Library
Toggles on/off the user library functions.
Declare
Warnings
Toggles on/off the declare warning messages during compiling.
Compiler Trace
Includes the following options:
Off
Turns off the compiler trace function.
File
Traces program file openings and closings.
Line
Traces compilation by line.
Symbol
Creates a report of procedures and the local and
global symbols they reference.
Using the Command Line Interface
5.4
Debugging
The debug command runs a program under the source level debugger.
The format for debug is:
debug filename
5.4.1
General Functions
?
Displays a list of available commands.
q/Esc
Exits the debugger and returns to the GAUSS command line.
+/-
Disables the last command repeat function.
5.4.2
Listing Functions
Displays a specified number of lines of source code in the current file.
lc
Displays source code in the current file starting with the current line.
ll file line
Displays source code in the named file starting with the specified line.
ll file
Displays source code in the named file starting with the first line.
ll line
Displays source code starting with the specified line. File does not change.
ll
Displays the next page of source code.
lp
Displays the previous page of source code.
5.4.3
Command
Line
l number
Execution Functions
s number
Executes the specified number of lines, stepping into procedures.
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GAUSS User Guide
n number
Executes the specified number of lines, stepping over procedures.
x number
Executes code from the beginning of the program to the specified line count, or
until a breakpoint is hit.
g [[args]]
Executes from the current line to the end of the program, stopping at
breakpoints. The optional arguments specify other stopping points. The syntax
for each optional argument is:
filename line period The debugger will stop every period times it reaches the
specified line in the named file.
filename line
The debugger will stop when it reaches the specified line
in the named file.
filename ,, period
The debugger will stop every period times it reaches any
line in the named file.
line period
The debugger will stop every period times it reaches the
specified line in the current file.
filename
The debugger will stop at every line in the named file.
line
The debugger will stop when it reaches the specified line
in the current file.
procedure period
The debugger will stop every period times it reaches the
first line in a called procedure.
procedure
The debugger will stop every time it reaches the first line
in a called procedure.
j [[args]]
Executes code to a specified line, procedure, or period in the file without
stopping at breakpoints. The optional arguments are the same as g, listed above.
jx number
Executes code to the execution count specified (number) without stopping at
breakpoints.
o
Executes the remainder of the current procedure (or to a breakpoint) and stops
at the next line in the calling procedure.
5-8
Using the Command Line Interface
5.4.4
View Commands
v [[vars]]
Searches for (a local variable, then a global variable) and displays the value of a
specified variable.
v$ [[vars]]
Searches for (a local variable, then a global variable) and displays the specified
character matrix.
The display properties of matrices and string arrays can be set using the following commands.
r
Specifies the number of rows to be shown.
c
Specifies the number of columns to be shown.
num,num
Specifies the indices of the upper left corner of the block to be shown.
w
Specifies the width of the columns to be shown.
p
Specifies the precision shown.
f
Specifies the format of the numbers as decimal, scientific, or auto format.
q
Quits the matrix viewer.
Command
Line
5.4.5
Breakpoint Commands
lb
Shows all the breakpoints currently defined.
b [[args]]
Sets a breakpoint in the code. The syntax for each optional argument is:
filename line period The debugger will stop every period times it reaches the
specified line in the named file.
filename line
The debugger will stop when it reaches the specified line
in the named file.
filename ,, period
The debugger will stop every period times it reaches any
line in the named file.
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GAUSS User Guide
d [[args]]
5.5
line period
The debugger will stop every period times it reaches the
specified line in the current file.
filename
The debugger will stop at every line in the named file.
line
The debugger will stop when it reaches the specified line
in the current file.
procedure period
The debugger will stop every period times it reaches the
first line in a called procedure.
procedure
The debugger will stop every time it reaches the first line
in a called procedure.
Removes a previously specified breakpoint. The optional arguments are the
same arguments as b, listed above.
Using the Source Browser in TGAUSS
To start the Source Browser in TGAUSS, type BROWSE followed by a symbol name. When the
Source Browser is active, the prompt displays Browse:. GAUSS searches through all active
libraries for the file in which the symbol is defined. If found, the file containing the source code is
opened in the default editor.
Wildcard (*) searches can also be used. When using wildcard searches, each symbol that the string
matches will be displayed on-screen in a numbered list. To select a specific command to view in
the default editor, select the number from the list.
The Source Browser will remain active until you type CTRL-C to return to the GAUSS prompt.
5-10
Language Fundamentals
6
GAUSS is a compiled language. GAUSS is also an interpreter. A compiled language, because
GAUSS scans the entire program once and translates it into a binary code before it starts to execute
the program. An interpreter, because the binary code is not the native code of the CPU. When
GAUSS executes the binary pseudocode it must “interpret” each instruction for the computer.
How can GAUSS be so fast if it is an interpreter? Two reasons. First, GAUSS has a fast
interpreter, and the binary compiled code is compact and efficient. Second, and most significantly,
GAUSS is a matrix language. It is designed to tackle problems that can be solved in terms of
matrix or vector equations. Much of the time lost in interpreting the pseudocode is made up in the
matrix or vector operations.
This chapter will enable you to understand the distinction between “compile time” and “execution
time”, two very different stages in the life of a GAUSS program.
Expressions
An expression is a matrix, string, constant, function reference, procedure reference, or any
combination of these joined by operators. An expression returns a result that can be assigned to a
6-1
Language
Fundamentals
6.1
GAUSS User Guide
variable with the assignment operator ‘=’.
6.2
Statements
A statement is a complete expression or command. Statements end with a semicolon.
y = x*3;
If an expression has no assignment operator (=), it will be assumed to be an implicit print
statement:
print x*3;
or
x*3;
Here is an example of a statement that is a command rather than an expression:
output on;
Commands cannot be used as a part of an expression.
There can be multiple statements on the same line as long as each statement is terminated with a
semicolon.
6-2
Language Fundamentals
6.2.1
Executable Statements
Executable statements are statements that can be “executed” over and over during the execution
phase of a GAUSS program (execution time). As an executable statement is compiled, binary code
is added to the program being compiled at the current location of the instruction pointer. This
binary code will be executed whenever the interpreter passes through this section of the program.
If this code is in a loop, it will be executed each iteration of the loop.
Here are some examples of executable statements:
y = 34.25;
print y;
x =
6.2.2
1 3 7 2 9 4 0 3 ;
Nonexecutable Statements
Nonexecutable statements are statements that have an effect only when the program is compiled
(compile time). They generate no executable code at the current location of the instruction pointer.
Here are two examples:
declare matrix x =
1 2 3 4 ;
Language
Fundamentals
external matrix ybar;
Procedure definitions are nonexecutable. They do not generate executable code at the current
location of the instruction pointer.
Here is an example:
6-3
GAUSS User Guide
zed = rndn(3,3);
proc sqrtinv(x);
local y;
y = sqrt(x);
retp(y+inv(x));
endp;
zsi = sqrtinv(zed);
There are two executable statements in the example above: the first line and the last line. In the
binary code that is generated, the last line will follow immediately after the first line. The last line
is the call to the procedure. This generates executable code. The procedure definition generates
no code at the current location of the instruction pointer.
There is code generated in the procedure definition, but it is isolated from the rest of the program.
It is executable only within the scope of the procedure and can be reached only by calling the
procedure.
6.3
Programs
A program is any set of statements that are run together at one time. There are two sections within
a program.
6.3.1
Main Section
The main section of the program is all of the code that is compiled together WITHOUT relying on
the autoloader. This means code that is in the main file or is included in the compilation of the
main file with an #include statement. ALL executable code should be in the main section.
There must always be a main section even if it consists only of a call to the one and only procedure
called in the program.
6-4
Language Fundamentals
6.3.2
Secondary Sections
Secondary sections of the program are files that are neither run directly nor included in the main
section with #include statements.
The secondary sections of the program can be left to the autoloader to locate and compile when
they are needed. Secondary sections must have only procedure definitions and other
nonexecutable statements.
#include statements are allowed in secondary sections as long as the file being included does not
violate the above criteria.
Here is an example of a secondary section:
declare matrix tol = 1.0e-15;
proc feq(a,b);
retp(abs(a-b) <= tol);
endp;
6.4
Compiler Directives
Compiler directives are commands that tell GAUSS how to process a program during compilation.
Directives determine what the final compiled form of a program will be. They can affect part or all
of the source code for a program. Directives are not executable statements and have no effect at
run-time. They do not take a semicolon at the end of the line.
Here are the compiler directives available in GAUSS:
#define
Define a case-insensitive text-replacement or flag variable.
6-5
Language
Fundamentals
The #include statement mentioned earlier is actually a compiler directive. It tells GAUSS to
compile code from a separate file as though it were actually part of the file being compiled. This
code is compiled in at the position of the #include statement.
GAUSS User Guide
#definecs
Define a case-sensitive text-replacement or flag variable.
#undef
Undefine a text-replacement or flag variable.
#ifdef
Compile code block if a variable has been #define’d.
#ifndef
Compile code block if a variable has not been #define’d.
#iflight
Compile code block if running GAUSS Light.
#ifdos
Compile code block if running DOS.
#ifos2win
Compile code block if running OS/2 or Windows.
#ifunix
Compile code block if running UNIX.
#else
Else clause for #if-#else-#endif code block.
#endif
End of #if-#else-#endif code block.
#include
Include code from another file in program.
#lineson
Compile program with line number and file name records.
#linesoff
Compile program without line number and file name records.
#srcfile
Insert source file name record at this point (currently used when
doing data loop translation).
#srcline
Insert source file line number record at this point (currently used
when doing data loop translation).
The #define statement can be used to define abstract constants. For example, you could define
the default graphics page size as:
#define hpage
#define vpage
6-6
9.0
6.855
Language Fundamentals
and then write your program using hpage and vpage. GAUSS will replace them with 9.0 and
6.855 when it compiles the program. This makes a program much more readable.
The #ifdef–#else–#endif directives allow you to conditionally compile sections of a program,
depending on whether a particular flag variable has been #define’d. For example:
#ifdef log_10
y = log(x);
#else
y = ln(x);
#endif
This allows the same program to calculate answers using different base logarithms, depending on
whether or not the program has a #define log_10 statement at the top.
#undef allows you to undefine text-replacement or flag variables so they no longer affect a
program, or so you can #define them again with a different value for a different section of the
program. If you use #definecs to define a case-sensitive variable, you must use the right case
when #undef’ing it.
With #lineson, #linesoff, #srcline, and #srcfile you can include line number and file
name records in your compiled code, so that run-time errors will be easier to track down.
#srcline and #srcfile are currently used by GAUSS when doing data loop translation.
For more information on line number tracking, see D, Section 16.3 and see D
D L, Section 19.3. See also #lineson in the GAUSS L R.
Language
Fundamentals
The syntax for #srcfile and #srcline is different than for the other directives that take
arguments. Typically, directives do not take arguments in parentheses; that is, they look like
keywords:
#define red 4
#srcfile and #srcline, however, do take their arguments in parentheses (like procedures):
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GAUSS User Guide
#srcline(12)
This allows you to place #srcline statements in the middle of GAUSS commands, so that line
numbers are reported precisely as you want them. For example:
#srcline(1)
#srcline(2)
#srcline(3)
#srcline(4)
print "Here is a multi-line "
"sentence--if it contains a run-time error, "
"you will know exactly "
"which part of the sentence has the problem.";
The argument supplied to #srcfile does not need quotes:
#srcfile(/gauss/test.e)
6.5
Procedures
A procedure allows you to define a new function which you can then use as if it were an intrinsic
function. It is called in the same way as an intrinsic function.
y = myproc(a,b,c);
Procedures are isolated from the rest of your program and cannot be entered except by calling
them. Some or all of the variables inside a procedure can be local variables . local variables
exist only when the procedure is actually executing and then disappear. Local variables cannot get
mixed up with other variables of the same name in your main program or in other procedures.
For details on defining and calling procedures, see P  K, chapter 8.
6-8
Language Fundamentals
6.6
Data Types
There are four basic data types in GAUSS, matrices, N-dimensional arrays, strings and string
arrays. It is not necessary to declare the type of a variable, but it is good programming practice to
respect the types of variables whenever possible. The data type and size can change in the course
of a program.
The declare statement, used for compile-time initialization, enforces type checking.
Short strings of up to 8 bytes can be entered into elements of matrices, to form character matrices
(For details, see C M, Section 6.6.7).
6.6.1
Constants
The following constant types are supported:
Decimal
Decimal constants can be either integer or floating point values:
1.34e-10
1.34e123
Language
Fundamentals
-1.34e+10
-1.34d-10
1.34d10
6-9
GAUSS User Guide
1.34d+10
123.456789345
Up to 18 consecutive digits before and after the decimal point(depending on the platform) are
significant, but the final result will be rounded to double precision if necessary. The range is the
same as for matrices (For details, see M, Section 6.6.2.
String
String constants are enclosed in quotation marks:
“This is a string.”
Hexadecimal Integer
Hexadecimal integer constants are prefixed with 0x:
0x0ab53def2
Hexadecimal Floating Point
Hexadecimal floating point constants are prefixed with 0v. This allows you to input a double
precision value exactly as you want using 16 hexadecimal digits. The highest order byte is to the
left:
0vfff8000000000000
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Language Fundamentals
6.6.2
Matrices
Matrices are 2-dimensional arrays of double precision numbers. All matrices are implicitly
complex, although if it consists only of zeros, the imaginary part may take up no space. Matrices
are stored in row major order. A 2×3 real matrix will be stored in the following way from the
lowest addressed element to the highest addressed element:
[1, 1] [1, 2] [1, 3] [2, 1] [2, 2] [2, 3]
A 2×3 complex matrix will be stored in the following way from the lowest addressed element to
the highest addressed element:
(real part)
[1, 1] [1, 2] [1, 3] [2, 1] [2, 2] [2, 3]
(imaginary part) [1, 1] [1, 2] [1, 3] [2, 1] [2, 2] [2, 3]
Conversion between complex and real matrices occurs automatically and is transparent to the user
in most cases. Functions are provided to provide explicit control when necessary.
All elements of a GAUSS matrix are stored in double precision floating point format, and each
takes up 8 bytes of memory. This is the IEEE 754 format:
Bytes
Data Type
Significant
Digits
Range
8
floating point
15–16
4.19x10−307 ≤ |X| ≤ 1.67x10+308
Matrices with only one element (1×1 matrices) are referred to as scalars, and matrices with only
one row or column (1×N or N×1 matrices) are referred to as vectors.
The majority of functions and operators in GAUSS take matrices as arguments. The following
functions and operators are used for defining, saving, and loading matrices:
6-11
Language
Fundamentals
Any matrix or vector can be indexed with two indices. Vectors can be indexed with one index.
Scalars can be indexed with one or two indices also, because scalars, vectors, and matrices are the
same data type to GAUSS.
GAUSS User Guide
[ ]
Indexing matrices.
=
Assignment operator.
|
Vertical concatenation.
∼
Horizontal concatenation.
con
Numeric input from keyboard.
cons
Character input from keyboard.
declare
Compile-time matrix or string initialization.
let
Matrix definition statement.
load
Load matrix (same as loadm).
readr
Read from a GAUSS matrix or data set file.
save
Save matrices, procedures and strings to disk.
saved
Convert a matrix to a GAUSS data set.
stof
Convert string to matrix.
submat
Extract a submatrix.
writer
Write data to a GAUSS data set.
Following are some examples of matrix definition statements.
An assignment statement followed by data enclosed in braces is an implicit let statement. Only
constants are allowed in let statements; operators are illegal. When braces are used in let
statements, commas are used to separate rows. The statement
let x =
or
6-12
1 2 3, 4 5 6, 7 8 9 ;
Language Fundamentals
x =
1 2 3, 4 5 6, 7 8 9 ;
will result in
1 2 3
x= 4 5 6
7 8 9
The statement
let x[3,3] = 1 2 3 4 5 6 7 8 9;
will result in
1 2 3
x= 4 5 6
7 8 9
The statement
let x[3,3] = 1;
will result in
Language
Fundamentals
1 1 1
x= 1 1 1
1 1 1
The statement
let x[3,3];
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GAUSS User Guide
will result in
0 0 0
x= 0 0 0
0 0 0
The statement
let x = 1 2 3 4 5 6 7 8 9;
will result in
1
2
3
4
x= 5
6
7
8
9
Complex constants can be entered in a let statement. In the following example, the + or - is not a
mathematical operator, but connects the two parts of a complex number. There should be no
spaces between the + or - and the parts of the number. If a number has both real and imaginary
parts, the trailing ‘i’ is not necessary. If a number has no real part, you can indicate that it is
imaginary by appending the ‘i’. The statement
let x[2,2] = 1+2i 3-4 5 6i;
will result in
x=
6-14
1 + 2i 3 − 4i
5
0 + 6i
Language Fundamentals
Complex constants can also be used with the declare, con and stof statements.
An “empty matrix” is a matrix that contains no data. Empty matrices are created with the let
statement and braces:
x = {};
Empty matrices are supported by several functions, including rows and cols and the
concatenation (∼,|) operators.
x = {};
hsec0 = hsec;
do until hsec-hsec0 > 6000;
x = x ˜ data_in(hsec-hsec0);
endo;
You can test whether a matrix is empty by entering rows(x), cols(x) and scalerr(x). If the
matrix is empty rows and cols will return a 0, and scalerr will return 65535.
The ∼ is the horizontal concatenation operator and the | is the vertical concatenation operator. The
statement
y = 1∼2|3∼4;
will be evaluated as
y = (1 ∼ 2) | (3 ∼ 4);
1 2
3 4
6-15
Language
Fundamentals
and will result in a 2×2 matrix because horizontal concatenation has precedence over vertical
concatenation:
GAUSS User Guide
The statement
y = 1+1∼2*2|3-2∼6/2;
will be evaluated as
y = ((1 + 1) ∼ (2 ∗ 2)) | ((3 − 2) ∼ (6/2));
and will result in a 2×2 matrix because the arithmetic operators have precedence over
concatenation:
2 4
1 3
For more information, see O P, Section 7.7.
The let command is used to initialize matrices with constant values:
let x[2,2] = 1 2 3 4;
Unlike the concatenation operators, it cannot be used to define matrices in terms of expressions
such as
y = x1-x2∼x2|x3*3∼x4;
The statement
y = x[1:3,5:8];
6-16
Language Fundamentals
will put the intersection of the first three rows and the fifth through eighth columns of x into the
matrix y.
The statement
y = x[1 3 1,5 5 9];
will create a 3×3 matrix y with the intersection of the specified rows and columns pulled from x
(in the indicated order).
The following code
let r = 1 3 1; let c = 5 5 9; y = x[r,c];
will have the same effect as the previous example, but is more general.
The statement
y[2,4] = 3;
will set the 2,4 element of the existing matrix y to 3. This statement is illegal if y does not have at
least 2 rows and 4 columns.
The statement
Language
Fundamentals
x = con(3,2);
will cause the following prompt to be printed in the window:
- (1,1)
6-17
GAUSS User Guide
indicating that the user should enter the [1,1] element of the matrix. Entering a number and then
pressing ENTER will cause a prompt for the next element of the matrix to appear. Pressing ? will
display a help screen, and pressing x will exit.
The statement
load x[] = b:mydata.asc
will load data contained in an ASCII file into an N×1 vector x. (Use rows(x) to find out how
many numbers were loaded, and use reshape(x,N,K) to reshape it to an N×K matrix).
The statement
load x;
will load the matrix x.fmt from disk (using the current load path) into the matrix x in memory.
The statement
open d1 = dat1;
x = readr(d1,100);
will read the first 100 rows of the GAUSS data set dat1.dat.
6.6.3
Sparse Matrices
Many GAUSS operators and commands support the sparse matrix data type. You may use any of
the following commands to create a sparse matrix:
6-18
denseToSp
Converts a dense matrix to a sparse matrix.
denseToSpRE
Converts a dense matrix to a sparse matrix, using a relative epsilon.
Language Fundamentals
packedToSp
Creates a sparse matrix from a packed matrix of non-zero values and
row and column indices.
spCreate
Creates a sparse matrix from vectors of non-zero values, row
indices, and column indices.
spEye
Creates a sparse identity matrix.
spOnes
Generates a sparse matrix containing only ones and zeros
spZeros
Creates a sparse matrix containing no non-zero values.
See S M, Chapter 9, for more information.
6.6.4
N-dimensional Arrays
Many GAUSS commands support arrays of N dimensions. The following commands may be used
to create and manipulate an N-dimensional array:
Concatenate conformable matrices and arrays in a user-specified
dimension.
aeye
Create an N-dimensional array in which the planes described by the
two trailing dimensions of the array are equal to the identity.
areshape
Reshape a scalar, matrix, or array into an array of user-specified size.
arrayalloc
Create an N-dimensional array with unspecified contents.
arrayinit
Create an N-dimensional array with a specified fill value.
mattoarray
Convert a matrix to a type array.
Language
Fundamentals
aconcat
See N-D A, Chapter 10, for a more detailed explanation.
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GAUSS User Guide
6.6.5
Strings
Strings can be used to store the names of files to be opened, messages to be printed, entire files, or
whatever else you might need. Any byte value is legal in a string from 0–255. The buffer where a
string is stored always contains a terminating byte of ASCII 0. This allows passing strings as
arguments to C functions through the Foreign Language Interface.
Here is a partial list of the functions for manipulating strings:
6-20
$+
Combine two strings into one long string.
ˆ
Interpret following name as a variable, not a literal.
chrs
Convert vector of ASCII codes to character string.
dttostr
Convert a matrix containing dates in DT scalar format to a string
array.
ftocv
Character representation of numbers in N×K matrix.
ftos
Character representation of numbers in 1×1 matrix.
ftostrC
Convert a matrix to a string array using a C language format
specification.
getf
Load ASCII or binary file into string.
indcv
Find index of element in character vector.
lower
Convert to lowercase.
stof
Convert string to floating point.
strindx
Find index of a string within a second string.
strlen
Length of a string.
strsect
Extract substring of string.
strsplit
Split an N×1 string vector into an N×K string array of the individual
tokens.
Language Fundamentals
strsplitPad
Split a string vector into a string array of the individual tokens. Pads
on the right with null strings.
strtodt
Convert a string array of dates to a matrix in DT scalar format.
strtof
Convert a string array to a numeric matrix.
strtofcplx
Convert a string array to a complex numeric matrix.
upper
Convert to uppercase.
vals
Convert from string to numeric vector of ASCII codes.
Strings can be created like this:
x = "example string";
or
x = cons;
/* keyboard input */
x = getf("myfile",0);
/* read a file into a string */
or
They can be printed like this:
Language
Fundamentals
print x;
A character matrix must have a ‘$’ prefixed to it in a print statement:
print $x;
6-21
GAUSS User Guide
A string can be saved to disk with the save command in a file with a .fst extension and then
loaded with the load command:
save x;
loads x;
or
loads x=x.fst;
The backslash is used as the escape character inside double quotes to enter special characters:
"\b"
"\e"
"\f"
"\g"
"\l"
"\r"
"\t"
"\\"
"\###"
backspace (ASCII 8)
escape (ASCII 27)
formfeed (ASCII 12)
beep (ASCII 7)
line feed (ASCII 10)
carriage return (ASCII 13)
tab (ASCII 9)
a backslash
the ASCII character whose decimal value is “###”.
When entering DOS pathnames in double quotes, two backslashes must be used to insert one
backslash:
st = "c:\\gauss\\myprog.prg";
An important use of strings and character elements of matrices is with the substitution operator (ˆ).
In the command
create f1 = olsdat with x,4,2;
6-22
Language Fundamentals
by default, GAUSS will interpret the olsdat as a literal; that is, the literal name of the GAUSS
data file you want to create. It will also interpret the x as the literal prefix string for the variable
names: x1 x2 x3 x4.
If you want to get the data set name from a string variable, the substitution operator (ˆ) could be
used as:
dataset="olsdat";
create f1=ˆdataset with x,4,2;
If you want to get the data set name from a string variable and the variable names from a character
vector, use
dataset="olsdat";
let vnames=age pay sex;
create f1=ˆdataset with ˆvnames,0,2;
The substitution operator (ˆ) works with load and save also:
lpath="/gauss/procs";
name="mydata";
load path=ˆlpath x=ˆname;
command="dir *.fmt";
The general syntax is:
Language
Fundamentals
ˆvariable name
Expressions are not allowed. The following commands are supported with the substitution
operator (ˆ):
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GAUSS User Guide
create f1=ˆdataset with ˆvnames,0,2;
create f1=ˆdataset using ˆcmdfile;
open f1=ˆdataset;
output file=ˆoutfile;
load x=ˆdatafile;
load path=ˆlpath x,y,z,t,w;
loadexe buf=ˆexefile;
save ˆname=x;
save path=ˆspath;
dos ˆcmdstr;
run ˆprog;
msym ˆmstring;
6.6.6
String Arrays
String arrays are N×K matrices of strings. Here is a partial list of the functions for manipulating
string arrays:
$|
Vertical string array concatenation operator.
$∼
Horizontal string array concatenation operator.
[ ]
Extract subarrays or individual strings from their corresponding
array,
or assign their values.
6-24
0
Transpose operator.
.0
Bookkeeping transpose operator.
declare
Initialize variables at compile time.
delete
Delete specified global symbols.
fgetsa
Read multiple lines of text from a file.
fgetsat
Reads multiple lines of text from a file, discarding newlines.
Language Fundamentals
format
Define output format for matrices, string arrays, and strings.
fputs
Write strings to a file.
fputst
Write strings to a file, appending newlines.
let
Initialize matrices, strings, and string arrays.
loads
Load a string or string array file (.fst file).
lprint
Print expressions to the printer.
lshow
Print global symbol table to the printer.
print
Print expressions on window and/or auxiliary output.
reshape
Reshape a matrix or string array to new dimensions.
save
Save matrix, string array, string, procedure, function or keyword to
disk and gives the disk file either a .fmt, .fst or .fcg extension.
show
Display global symbol table.
sortcc
Quick-sort rows of matrix or string array based on character column.
type
Indicate whether variable passed as argument is matrix, string, or
string array.
typecv
Indicate whether variables named in argument are strings, string
arrays, matrices, procedures, functions or keywords.
Access the global variable named by a string array.
varput
Assign the global variable named by a string array.
vec
Stack columns of a matrix or string array to form a column vector.
vecr
Stack rows of a matrix or string array to form a column vector.
String arrays are created through the use of the string array concatenation operators. Below is a
contrast of the horizontal string and horizontal string array concatenation operators.
6-25
Language
Fundamentals
varget
GAUSS User Guide
x = "age";
y = "pay";
n = "sex";
s = x $+ y $+ n;
sa = x $∼ y $∼ n;
s = agepaysex
sa = age
6.6.7
pay
sex
Character Matrices
Matrices can have either numeric or character elements. For convenience, a matrix containing
character elements is referred to as a character matrix.
A character matrix is not a separate data type, but gives you the ability to store and manipulate
data elements that are composed of ASCII characters as well as floating point numbers. For
example, you may want to concatenate a column vector containing the names of the variables in an
analysis onto a matrix containing the coefficients, standard errors, t-statistic, and p-value. You can
then print out the entire matrix with a separate format for each column with one call to the
function printfm.
The logic of the programs will dictate the type of data assigned to a matrix, and the increased
flexibility allowed by being able to bundle both types of data together in a single matrix can be
very powerful. You could, for instance, create a moment matrix from your data, concatenate a new
row onto it containing the names of the variables and save it to disk with the save command.
Numeric matrices are double precision, which means that each element is stored in 8 bytes. A
character matrix can thus have elements of up to 8 characters.
GAUSS does not automatically keep track of whether a matrix contains character or numeric
information. The ASCII to GAUSS conversion program ATOG will record the types of variables
in a data set when it creates it. The create command will, also. The function vartypef gets a
vector of variable type information from a data set. This vector of ones and zeros can be used by
printfm when printing your data. Since GAUSS does not know whether a matrix has character or
6-26
Language Fundamentals
numeric information, it is up to you to specify which type of data it contains when printing the
contents of the matrix. (For details, see print and printfm in the GAUSS L R.)
Most functions that take a string argument will take an element of a character matrix also,
interpreting it as a string of up to 8 characters.
6.6.8
Date and Time Formats
DT Scalar Format
The DT scalar format is a double precision representation of the date and time. In the DT scalar
format, the number
20010421183207
represents 18:32:07 or 6:32:07 PM on April 21, 2001.
DTV Vector Format
The DTV vector is a 1×8 vector. The format for the DTV vector is:
Year
Month, 1-12
Day of month, 1-31
Hour of day, 0-23
Minute of hour, 0-59
Second of minute, 0-59
Day of week, 0-6 where 0 is Sunday
Day since beginning of year, 0-365
Language
Fundamentals
[1]
[2]
[3]
[4]
[5]
[6]
[7]
[8]
UTC Scalar Format
The UTC scalar format is the number of seconds since January 1, 1970, Greenwich Mean Time.
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GAUSS User Guide
6.6.9
Special Data Types
The IEEE floating point format has many encodings that have special meaning. The print
command will print them accurately so that you can tell if your calculation is producing
meaningful results.
NaN
There are many floating point encodings which do not correspond to a real number. These
encodings are referred to as NaN’s. NaN stands for Not A Number.
Certain numerical errors will cause the math coprocessor to create a NaN called an “indefinite”.
This will be printed as a -NaN when using the print command. These values are created by the
following operations:
• +∞ plus −∞
• +∞ minus +∞
• −∞ minus −∞
• 0∗∞
• ∞/∞
• 0/0
• Operations where one or both operands is a NaN
• Trigonometric functions involving ∞
INF
When the math coprocessor overflows, the result will be a properly signed infinity. Subsequent
calculations will not deal well with an infinity; it usually signals an error in your program. The
result of an operation involving an infinity is most often a NaN.
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Language Fundamentals
DEN, UNN
When some math coprocessors underflow, they may do so gradually by shifting the significand of
the number as necessary to keep the exponent in range. The result of this is a denormal (DEN).
When denormals are used in calculations, they are usually handled automatically in an appropriate
way. The result will either be an unnormal (UNN), which like the denormal represents a number
very close to zero, or a normal, depending on how significant the effect of the denormal was in the
calculation. In some cases the result will be a NaN.
Following are some procedures for dealing with these values. These procedures are not defined in
the Run-Time Library. If you want to use them, you will need to define them yourself.
The procedure isindef will return 1 (true) if the matrix passed to it contains any NaN’s that are
the indefinite mentioned earlier. The GAUSS missing value code as well as GAUSS scalar error
codes are NaN’s, but this procedure tests only for indefinite:
proc isindef(x);
retp(not x $/= __INDEFn);
endp;
Be sure to call gausset before calling isindef. gausset will initialize the value of the global
__INDEFn to a platform-specific encoding.
The procedure normal will return a matrix with all denormals and unnormals set to zero.
proc normal(x);
retp(x .* (abs(x) .> 4.19e-307));
endp;
Language
Fundamentals
The procedure isinf, will return 1 (true) if the matrix passed to it contains any infinities:
proc isinf(x);
local plus,minus;
plus = __INFp;
6-29
GAUSS User Guide
minus = __INFn;
retp(not x /= plus or not x /= minus);
endp;
Be sure to call gausset before calling isinf. gausset will initialize the values of the globals
__INFn and __INFp to platform specific encodings.
6.7
Operator Precedence
The order in which an expression is evaluated is determined by the precedence of the operators
involved and the order in which they are used. For example, the * and / operators have a higher
precedence than the + and - operators. In expressions that contain these operators, the operand
pairs associated with the * or / operator are evaluated first. Whether * or / is evaluated first
depends on which comes first in the particular expression. For a listing of the precedence of all
operators, see O P, Section 7.7.
The expression
-5+3/4+6*3
is evaluated as
(−5) + (3/4) + (6 ∗ 3)
Within a term, operators of equal precedence are evaluated from left to right.
The term
2ˆ3ˆ7
6-30
Language Fundamentals
is evaluated
(23 )7
In the expression
f1(x)*f2(y)
f1 is evaluated before f2.
Here are some examples:
Evaluation
a+b*c+d
(a + (b ∗ c)) + d
-2+4-6*inv(8)/9
((−2) + 4) − ((6 ∗ inv(8))/9)
3.14ˆ5*6/(2+sqrt(3)/4)
((3.145 ) ∗ 6)/(2 + (sqrt(3)/4))
-a+b*cˆ2
(−a) + (b ∗ (c2 ))
a+b-c+d-e
(((a + b) − c) + d) − e
aˆbˆc*d
((ab )c ) ∗ d
a*b/d*c
((a ∗ b)/d) ∗ c
aˆb+c*d
(ab ) + (c ∗ d)
2ˆ4!
2(4!)
2*3!
2 ∗ (3!)
Language
Fundamentals
6.8
Expression
Flow Control
A computer language needs facilities for decision making and looping to control the order in
which computations are done. GAUSS has several kinds of flow control statements.
6-31
GAUSS User Guide
6.8.1
Looping
do loop
The do statement can be used in GAUSS to control looping.
do while scalar expression; /* loop if expression is true */
.
.
statements
.
.
endo;
also
do until scalar expression; /* loop if expression is false */
.
.
statements
.
.
endo;
The scalar expression is any expression that returns a scalar result. The expression will be
evaluated as TRUE if its real part is nonzero and FALSE if it is zero. There is no counter variable
that is automatically incremented in a do loop. If one is used, it must be set to its initial value
before the loop is entered and explicitly incremented or decremented inside the loop.
The following example illustrates nested do loops that use counter variables.
format /rdn 1,0;
space = "
";
comma = ",";
i = 1;
do while i <= 4;
j = 1;
6-32
Language Fundamentals
do while j <= 3;
print space i comma j;;
j = j+1;
endo;
i = i+1;
print;
endo;
This will print:
1, 1
2, 1
3, 1
4, 1
1, 2
2, 2
3, 2
4, 2
1, 3
2, 3
3, 3
4, 3
Use the relational and logical operators without the dot ‘.’ in the expression that controls a do
loop. These operators always return a scalar result.
break and continue are used within do loops to control execution flow. When break is
encountered, the program will jump to the statement following the endo. This terminates the loop.
When continue is encountered, the program will jump up to the top of the loop and reevaluate
the while or until expression. This allows you to reiterate the loop without executing any more
of the statements inside the loop:
Language
Fundamentals
do until eof(fp);
/* continue jumps here */
x = packr(readr(fp,100));
if scalmiss(x);
continue;
/* iterate again */
endif;
s = s + sumc(x);
count = count + rows(x);
if count >= 10000;
break;
/* break out of loop */
endif;
endo;
mean = s / count;
/* break jumps here */
6-33
GAUSS User Guide
for loop
The fastest looping construct in GAUSS is the for loop:
for counter (start, stop, step);
.
.
statements
.
.
endfor;
counter is the literal name of the counter variable. start, stop and step are scalar expressions. start
is the initial value, stop is the final value and step is the increment.
break and continue are also supported by for loops. (For more information, see for in the
GAUSS L R.)
6.8.2
Conditional Branching
The if statement controls conditional branching:
if scalar expression;
.
.
statements
.
.
elseif scalar expression;
.
.
statements
.
.
6-34
Language Fundamentals
else;
.
.
statements
.
.
endif;
The scalar expression is any expression that returns a scalar result. The expression will be
evaluated as TRUE if its real part is nonzero and FALSE if it is zero.
GAUSS will test the expression after the if statement. If it is TRUE, then the first list of
statements is executed. If it is FALSE, then GAUSS will move to the expression after the first
elseif statement, if there is one, and test it. It will keep testing expressions and will execute the
first list of statements that corresponds to a TRUE expression. If no expression is TRUE, then the
list of statements following the else statement is executed. After the appropriate list of statements
is executed, the program will go to the statement following the endif and continue on.
Use the relational and logical operators without the dot ‘.’ in the expression that controls an if or
elseif statement. These operators always return a scalar result.
if statements can be nested.
One endif is required per if clause. If an else statement is used, there may be only one per if
clause. There may be as many elseif’s as are required. There need not be any elseif’s or any
else statement within an if clause.
6.8.3
Unconditional Branching
goto
A goto is an unconditional jump to a label with no return:
6-35
Language
Fundamentals
The goto and gosub statements control unconditional branching. The target of both a goto and a
gosub is a label.
GAUSS User Guide
label:
.
.
goto label;
Parameters can be passed with a goto. The number of parameters is limited by available stack
space. This is helpful for common exit routines:
.
.
goto errout("Matrix singular");
.
.
goto errout("File not found");
.
.
errout:
pop errmsg;
errorlog errmsg;
end;
gosub
With a gosub, the address of the gosub statement is remembered and when a return statement is
encountered, the program will resume executing at the statement following the gosub.
Parameters can be passed with a gosub in the same way as a goto. With a gosub it is also
possible to return parameters with the return statement.
Subroutines are not isolated from the rest of your program and the variables referred to between
the label and the return statement can be accessed from other places in your program.
Since a subroutine is only an address marked by a label, there can be subroutines inside of
procedures. The variables used in these subroutines are the same variables that are known inside
the procedure. They will not be unique to the subroutine, but they may be locals that are unique to
6-36
Language Fundamentals
the procedure that the subroutine is in. (For details, see gosub in the GAUSS L
R.)
6.9
Functions
Single line functions that return one item can be defined with the fn statement.
fn area(r) = pi * r * r;
These functions can be called in the same way as intrinsic functions. The above function could be
used in the following program sequence.
diameter = 3;
radius = 3 / 2;
a = area(radius);
6.10
Rules of Syntax
This section lists the general rules of syntax for GAUSS programs.
6.10.1
Statements
(gauss) x=5; z=rndn(3,3); y=x+z
6-37
Language
Fundamentals
A GAUSS program consists of a series of statements. A statement is a complete expression or
command. Statements in GAUSS end with a semicolon with one exception: from the GAUSS
command line, the final semicolon in an interactive program is implicit if it is not explicitly given:
GAUSS User Guide
Column position is not significant. Blank lines are allowed. Inside a statement and outside of
double quotes, the carriage return/line feed at the end of a physical line will be converted to a
space character as the program is compiled.
A statement containing a quoted string can be continued across several lines with a backslash as
follows.
s = "This is one really long string that would be "\
"difficult to assign in just a single line.";
6.10.2
Case
GAUSS does not distinguish between uppercase and lowercase except inside double quotes.
6.10.3
Comments
// This comments out all text between the ’//’ and the end of
// the line
/* This kind of comment can be nested */
@ We consider this kind of comment to be obsolete, but it is
supported for backwards compatibility @
6.10.4
Extraneous Spaces
Extraneous spaces are significant in print and lprint statements where the space is a delimiter
between expressions:
print x y z;
6-38
Language Fundamentals
In print and lprint statements, spaces can be used in expressions that are in parentheses:
print (x * y) (x + y);
6.10.5
Symbol Names
The names of matrices, strings, procedures, and functions can be up to 32 characters long. The
characters must be alphanumeric or an underscore. The first character must be alphabetic or an
underscore.
6.10.6
Labels
A label is used as the target of a goto or a gosub. The rules for naming labels are the same as for
matrices, strings, procedures, and functions. A label is followed immediately by a colon:
here:
The reference to a label does not use a colon:
goto here;
6.10.7
Assignment Statements
Language
Fundamentals
The assignment operator is the equal sign ‘=’:
y = x + z;
Multiple assignments must be enclosed in braces ‘{ }’:
6-39
GAUSS User Guide
mant,pow
= base10(x);
The comparison operator (equal to) is two equal signs ‘= =’:
if x =\,= y;
print "x is equal to y";
endif;
6.10.8
Function Arguments
The arguments to functions are enclosed in parentheses ‘( )’:
y = sqrt(x);
6.10.9
Indexing Matrices
Brackets ‘[ ]’ are used to index matrices:
x = { 1
3
3
8
6
2
7
7
9
1
3,
5,
4,
5,
8 };
y = x[3,3];
z = x[1 2:4,1 3];
Vectors can be indexed with either one or two indices:
v = 1 2 3 4 5 6 7 8 9 ;
k = v[3];
j = v[1,6:9];
6-40
Language Fundamentals
x[2,3] returns the element in the second row and the third column of x.
x[1 3 5,4 7] returns the submatrix that is the intersection of rows 1, 3, and 5 and columns 4 and
7.
x[.,3] returns the third column of x.
x[3:5,.] returns the submatrix containing the third through the fifth rows of x.
The indexing operator will take vector arguments for submatrix extraction or submatrix
assignments:
y = x[rv,cv];
y[rv,cv] = x;
rv and cv can be any expressions returning vectors or matrices. The elements of rv will be used
as the row indices and the elements of cv will be used as the column indices. If rv is a scalar 0, all
rows will be used; if cv is a scalar 0, all columns will be used. If a vector is used in an index
expression, it is illegal to use the space operator or the colon operator on the same side of the
comma as the vector.
6.10.10
Arrays of Matrices and Strings
It is possible to index sets of matrices or strings using the varget function.
mvec = { x y z a };
i = 2;
g = inv(varget(mvec[i]));
6-41
Language
Fundamentals
In this example, a set of matrix names is assigned to mvec. The name y is indexed from mvec and
passed to varget which will return the global matrix y. The returned matrix is inverted and
assigned to g:
GAUSS User Guide
The following procedure can be used to index the matrices in mvec more directly:
proc imvec(i);
retp(varget(mvec[i]));
endp;
Then imvec(i) will equal the matrix whose name is in the ith element of mvec.
In the example above, the procedure imvec() was written so that it always operates on the vector
mvec. The following procedure makes it possible to pass in the vector of names being used:
proc get(array,i);
retp(varget(array[i]));
endp;
Then get(mvec,3) will return the 3rd matrix listed in mvec.
proc put(x,array,i);
retp(varput(x,array[i]));
endp;
And put(x,mvec,3) will assign x to the 3rd matrix listed in mvec and return a 1 if successful or a
0 if it fails.
6.10.11
Arrays of Procedures
It is also possible to index procedures. The ampersand operator (&) is used to return a pointer to a
procedure.
Assume that f1, f2, and f3 are procedures that take a single argument. The following code
defines a procedure fi that will return the value of the ith procedure, evaluated at x.
6-42
Language Fundamentals
nms = &f1 | &f2 | &f3;
proc fi(x,i);
local f;
f = nms[i];
local f:proc;
retp( f(x) );
endp;
fi(x,2) will return f2(x). The ampersand is used to return the pointers to the procedures. nms is
a numeric vector that contains a set of pointers. The local statement is used twice. The first tells
the compiler that f is a local matrix. The ith pointer, which is just a number, is assigned to f. Then
the second local statement tells the compiler to treat f as a procedure from this point on; thus the
subsequent statement f(x) is interpreted as a procedure call.
Language
Fundamentals
6-43
Operators
Operators
7.1
7
Element-by-Element Operators
Element-by-element operators share common rules of conformability. Some functions that have
two arguments also operate according to the same rules.
Element-by-element operators handle those situations in which matrices are not conformable
according to standard rules of matrix algebra. When a matrix is said to be E×E conformable, it
refers to this element-by-element conformability . The following cases are supported:
matrix
op
matrix
matrix
scalar
op
op
scalar
matrix
matrix
vector
op
op
vector
matrix
vector
op
vector
7-1
GAUSS User Guide
In a typical expression involving an element-by-element operator
z = x + y;
conformability is defined as follows:
• If x and y are the same size, the operations are carried out corresponding element by
corresponding element:
1 3 2
x= 4 5 1
3 7 4
2 4 3
y= 3 1 4
6 1 2
3 7 5
z= 7 6 5
9 8 6
• If x is a matrix and y is a scalar, or vice versa, then the scalar is operated on with respect to
every element in the matrix. For example, x + 2 will add 2 to every element of x:
1 3 2
x= 4 5 1
3 7 4
y=
2
3 5 4
z= 6 7 3
5 9 6
7-2
• If x is an N×1 column vector and y is an N×K matrix, or vice versa, the vector is swept
“across” the matrix:
vector
matrix
1
−→
2
4
3
4
−→
3
1
4
3
−→
6
1
2
result
3
5
4
7
5
8
9
4
5
• If x is an 1×K column vector and y is an N×K matrix, or vice versa, then the vector is swept
“down” the matrix:
vector
matrix
result
2
4
3
↓
↓
↓
2
4
3
3
1
4
6
1
2
4
8
6
5
5
7
8
5
5
• When one argument is a row vector and the other is a column vector, the result of an
element-by-element operation will be the “table” of the two:
7-3
Operators
Operators
GAUSS User Guide
row vector
column vector
2
4
3
1
3
5
7
6
4
2
4
6
5
3
5
7
9
8
6
If x and y are such that none of these conditions apply, the matrices are not conformable to these
operations and an error message will be generated.
7.2
Matrix Operators
The following operators work on matrices. Some assume numeric data and others will work on
either character or numeric data.
7.2.1
Numeric Operators
For details on how matrix conformability is defined for element-by-element operators, see
E--E O, Section 7.1.
+
Addition
y = x + z;
Performs element-by-element addition.
−
Subtraction or negation
y = x - z;
y = -k;
7-4
Performs element-by-element subtraction or the negation of all elements, depending on
context.
*
Matrix multiplication or multiplication
y = x * z;
When z has the same number of rows as x has columns, this will perform matrix
multiplication (inner product). If x or z are scalar, this performs standard
element-by-element multiplication.
/
Division or linear equation solution
x = b / A;
If A and b are scalars, this performs standard division. If one of the operands is a matrix and
the other is scalar, the result is a matrix the same size with the results of the divisions
between the scalar and the corresponding elements of the matrix. Use ./ for
element-by-element division of matrices.
If b and A are conformable, this operator solves the linear matrix equation
Ax = b
Linear equation solution is performed in the following cases:
• If A is a square matrix and has the same number of rows as b, this statement will solve
the system of linear equations using an LU decomposition.
• If A is rectangular with the same number of rows as b, this statement will produce the
least squares solutions by forming the normal equations and using the Cholesky
decomposition to get the solution:
x=
A0 b
A0 A
If trap 2 is set, missing values will be handled with pairwise deletion.
%
Modulo division
7-5
Operators
Operators
GAUSS User Guide
y = x %z;
For integers, this returns the integer value that is the remainder of the integer division of x
by z. If x or z is noninteger, it will first be rounded to the nearest integer. This is an
element-by-element operator.
!
Factorial
y = x!;
Computes the factorial of every element in the matrix x. Nonintegers are rounded to the
nearest integer before the factorial operator is applied. This will not work with complex
matrices. If x is complex, a fatal error will be generated.
.*
Element-by-element multiplication
y = x .* z;
If x is a column vector, and z is a row vector (or vice versa), the “outer product” or “table” of
the two will be computed. (For comformability rules, see E--E O,
Section 7.1.)
./
Element-by-element division
y = x ./ z;
ˆ
Element-by-element exponentiation
y = xˆz;
If x is negative, z must be an integer.
.ˆ
Same as ˆ
.*. Kronecker (tensor) product
7-6
y = x .*.
z;
This results in a matrix in which every element in x has been multiplied (scalar
multiplication) by the matrix z. For example:
x = { 1 2,
3 4 };
z = { 4 5 6,
7 8 9 };
y = x .*. z;
x=
1 2
3 4
z=
4 5 6
7 8 9
4 5 6 8 10 12
7 8 9 14 16 18
y=
12 15 18 16 20 24
21 24 27 28 32 36
∗∼
Horizontal direct product
z = x *∼ y;
x=
1 2
3 4
y=
5 6
7 8
z=
5 6 10 12
21 24 28 32
The input matrices x and y must have the same number of rows. The result will have
cols(x) * cols(y) columns.
7-7
Operators
Operators
GAUSS User Guide
7.2.2
0
Other Matrix Operators
Transpose operator
y = x0 ;
The columns of y will contain the same values as the rows of x and the rows of y will
contain the same values as the columns of x. For complex matrices this computes the
complex conjugate transpose.
If an operand immediately follows the transpose operator, the 0 will be interpreted as 0 *.
Thus y = x0 x is equivalent to y = x0 *x.
.0
Bookkeeping transpose operator
y = x.0 ;
This is provided primarily as a matrix handling tool for complex matrices. For all matrices,
the columns of y will contain the same values as the rows of x and the rows of y will contain
the same values as the columns of x. The complex conjugate transpose is NOT computed
when you use .0 .
If an operand immediately follows the bookkeeping transpose operator, the .0 will be
interpreted as .0 *. Thus y = x.0 x is equivalent to y = x.0 *x.
|
Vertical concatenation
z = x|y;
x=
1 2 3
3 4 5
y= 7 8 9
1 2 3
z= 3 4 5
7 8 9
7-8
∼
Horizontal concatenation
z = x∼y;
7.3
x=
1 2
3 4
y=
5 6
7 8
z=
1 2 5 6
3 4 7 8
Relational Operators
For details on how matrix conformability is defined for element-by-element operators, see
E--E O, Section 7.1
Each of these operators has two equivalent representations. Either can be used (for example, < or
lt), depending only upon preference. The alphabetic form should be surrounded by spaces.
A third form of these operators has a ‘$’ and is used for comparisons between character data and
for comparisons between strings or string arrays. The comparisons are done byte by byte starting
with the lowest addressed byte of the elements being compared.
The equality comparison operators (<=, = =, >=, /=) and their dot equivalents can be used to test
for missing values and the NaN that is created by floating point exceptions. Less than and greater
than comparisons are not meaningful with missings or NaN’s, but equal and not equal are valid.
These operators are sign-insensitive for missings, NaN’s, and zeros.
The string ‘$’ versions of these operators can also be used to test missings, NaN’s and zeros.
Because they do a strict byte-to-byte comparison, they are sensitive to the sign bit. Missings,
NaN’s, and zeros can all have the sign bit set to 0 or 1, depending on how they were generated and
have been used in a program.
7-9
Operators
Operators
GAUSS User Guide
If the relational operator is NOT preceded by a dot ‘.’, then the result is always a scalar 1 or 0,
based upon a comparison of all elements of x and y. All comparisons must be true for the
relational operator to return TRUE.
By this definition, then
if x /= y;
is interpreted as: “if every element of x is not equal to the corresponding element of y”. To check
if two matrices are not identical, use
if not x = = y;
For complex matrices, the = =, /=, .= = and ./= operators compare both the real and imaginary
parts of the matrices; all other relational operators compare only the real parts.
• Less than
z = x < y;
z = x lt y;
z = x $< y;
• Less than or equal to
z = x <= y;
z = x le y;
z = x $<= y;
• Equal to
z = x = = y;
7-10
z = x eq y;
z = x $= = y;
• Not equal
z = x /= y;
z = x ne y;
z = x $/= y;
• Greater than or equal to
z = x >= y;
z = x ge y;
z = x $>= y;
• Greater than
z = x > y;
z = x gt y;
z = x $> y;
If the relational operator IS preceded by a dot ‘.’, then the result will be a matrix of 1’s and 0’s,
based upon an element-by-element comparison of x and y.
• Element-by-element less than
z = x .< y;
z = x .lt y;
z = x .$< y;
7-11
Operators
Operators
GAUSS User Guide
• Element-by-element less than or equal to
z = x .<= y;
z = x .le y;
z = x .$<= y;
• Element-by-element equal to
z = x .= = y;
z = x .eq y;
z = x .$= = y;
• Element-by-element not equal to
z = x ./= y;
z = x .ne y;
z = x .$/= y;
• Element-by-element greater than or equal to
z = x .>= y;
z = x .ge y;
z = x .$>= y;
• Element-by-element greater than
z = x .> y;
z = x .gt y;
z = x .$> y;
7-12
7.4
Logical Operators
The logical operators perform logical or Boolean operations on numeric values. On input a
nonzero value is considered TRUE and a zero value is considered FALSE. The logical operators
return a 1 if TRUE and a 0 if FALSE. Decisions are based on the following truth tables:
Complement
not X
F
T
X
T
F
Conjunction
X
T
T
F
F
Y
T
F
T
F
X and Y
T
F
F
F
Disjunction
X
T
T
F
F
Y
T
F
T
F
X or Y
T
T
T
F
7-13
Operators
Operators
GAUSS User Guide
Exclusive Or
X
T
T
F
F
Y
T
F
T
F
X xor Y
F
T
T
F
Equivalence
X
T
T
F
F
Y
T
F
T
F
X eqv Y
T
F
F
T
For complex matrices, the logical operators consider only the real part of the matrices.
The following operators require scalar arguments. These are the ones to use in if and do
statements:
• Complement
z = not x;
• Conjunction
z = x and y;
• Disjunction
z = x or y;
• Exclusive or
z = x xor y;
7-14
• Equivalence
z = x eqv y;
If the logical operator is preceded by a dot ‘.’, the result will be a matrix of 1’s and 0’s based upon
an element-by-element logical comparison of x and y:
• Element-by-element logical complement
z = .not x;
• Element-by-element conjunction
z = x .and y;
• Element-by-element disjunction
z = x .or y;
• Element-by-element exclusive or
z = x .xor y;
• Element-by-element equivalence
z = x .eqv y;
7.5
Other Operators
Assignment Operator
Assignments are done with one equal sign:
y = 3;
7-15
Operators
Operators
GAUSS User Guide
Comma
Commas are used to delimit lists:
clear x,y,z;
to separate row indices from column indices within brackets:
y = x[3,5];
and to separate arguments of functions within parentheses:
y = momentd(x,d);
Period
Dots are used in brackets to signify “all rows” or “all columns”:
y = x[.,5];
Space
Spaces are used inside of index brackets to separate indices:
y = x[1 3 5,3 5 9];
No extraneous spaces are allowed immediately before or after the comma, or immediately after the
left bracket or before the right bracket.
Spaces are also used in print and lprint statements to separate the separate expressions to be
printed:
7-16
print x/2 2*sqrt(x);
No extraneous spaces are allowed within expressions in print or lprint statements unless the
expression is enclosed in parentheses:
print (x / 2) (2 * sqrt(x));
Colon
A colon is used within brackets to create a continuous range of indices:
y = x[1:5,.];
Ampersand
The (&) ampersand operator will return a pointer to a procedure (proc), function (fn), or structure
(struct). It is used when passing procedures or functions to other functions, when indexing
procedures, and when initializing structure pointers. (For more information, see I
P, Section 8.5 or S P, Section 12.2.)
String Concatenation
x = "dog";
y = "cat";
z = x $+ y;
print z;
dogcat
If the first argument is of type string, the result will be of type string. If the first argument is of
type matrix, the result will be of type matrix. Here are some examples:
7-17
Operators
Operators
GAUSS User Guide
y = 0 $+ "caterpillar";
The result will be a 1×1 matrix containing ‘caterpil’.
y = zeros(3,1) $+ "cat";
The result will be a 3×1 matrix, each element containing ‘cat’.
If we use the y created above in the following:
k = y $+ "fish";
The result will be a 3×1 matrix with each element containing ‘catfish’.
If we then use k created above:
t = "" $+ k[1,1];
The result will be a string containing ‘catfish’.
If we used the same k to create z as follows:
z = "dog" $+ k[1,1];
The resulting z will be a string containing ‘dogcatfish’.
String Array Concatenation
$| Vertical string array concatenation
7-18
x = "dog";
y = "fish";
k = x $| y;
print k;
dog
fish
$∼ Horizontal string array concatenation
x = "dog";
y = "fish";
k = x $˜ y;
print k;
dog
fish
String Variable Substitution
In a command like the following:
create f1 = olsdat with x,4,2;
by default GAUSS will interpret olsdat as the literal name of the GAUSS data file you want to
create. It will also interpret x as the literal prefix string for the variable names x1 x2 x3 x4.
To get the data set name from a string variable, the substitution operator (ˆ) could be used as
follows:
dataset = "olsdat";
create f1 = ˆdataset with x,4,2;
To get the data set name from a string variable and the variable names from a character vector, use
the following:
7-19
Operators
Operators
GAUSS User Guide
dataset = "olsdat";
vnames = { age, pay, sex };
create f1 = ˆdataset with ˆvnames,0,2;
The general syntax is:
ˆvariable name
Expressions are not allowed.
The following commands are currently supported with the substitution operator (ˆ) in the current
version.
create f1 = ˆdataset with ˆvnames,0,2;
create f1 = ˆdataset using ˆcmdfile;
open f1 = ˆdataset;
output file = ˆoutfile;
load x = ˆdatafile;
load path = ˆlpath x,y,z,t,w;
loadexe buf = ˆexefile;
save ˆname = x;
save path = ˆspath;
dos ˆcmdstr;
run ˆprog;
msym ˆmstring;
7.6
Using Dot Operators with Constants
When you use those operators preceded by a ‘.’ (dot operators) with a scalar integer constant,
insert a space between the constant and any following dot operator. Otherwise, the dot will be
interpreted as part of the scalar; that is, the decimal point. For example:
7-20
let y = 1 2 3;
x = 2.<y;
will return x as a scalar 0, not a vector of 0’s and 1’s, because
x = 2.<y;
is interpreted as
x = 2. < y;
and not as
x = 2 .< y;
Be careful when using the dot relational operators (.<, .<=, .= =, ./=, .>, .>=). The same
problem can occur with other dot operators, also. For example:
let x = 1 1 1;
y = x./2./x;
will return y as a scalar .5 rather than a vector of .5’s, because
y = x./2./x;
is interpreted as
y = (x ./ 2.) / x;
7-21
Operators
Operators
GAUSS User Guide
not
y = (x ./ 2) ./ x;
The second division, then, is handled as a matrix division rather than an element-by-element
division.
7.7
Operator Precedence
The order in which an expression is evaluated is determined by the precedence of the operators
involved and the order in which they are used. For example, the * and / operators have a higher
precedence than the + and − operators. In expressions that contain the above operators, the
operand pairs associated with the * or / operator are evaluated first. Whether * or / is evaluated
first depends on which comes first in the particular expression.
The expression
-5+3/4+6*3
is evaluated as
(-5)+(3/4)+(6*3)
Within a term, operators of equal precedence are evaluated from left to right. The precedence of
all operators, from the highest to the lowest, is listed in the following table:
7-22
Operator
.0
0
!
.ˆ
ˆ
(unary -)
*
*∼
.*
.*.
./
/
%
$+
+
∼
|
.$/=
.$<
.$<=
.$= =
.$>
Precedence
90
90
89
85
85
83
80
80
80
80
80
80
75
70
70
70
68
67
65
65
65
65
65
Operator
.$>=
./=
.<
.<=
.= =
.>
.>=
.eq
.ge
.gt
.le
.lt
.ne
.not
.and
.or
.xor
.eqv
$/=
$<
$<=
$= =
$>
Precedence
65
65
65
65
65
65
65
65
65
65
65
65
65
64
63
62
61
60
55
55
55
55
55
Operator
$>=
/=
<
<=
==
>
>=
eq
ge
gt
le
lt
ne
not
and
or
xor
eqv
(space)
:
=
Precedence
55
55
55
55
55
55
55
55
55
55
55
55
55
49
48
47
46
45
35
35
10
7-23
Operators
Operators
8
Procedures are multiple-line, recursive functions that can have either local or global variables.
Procedures allow a large computing task to be written as a collection of smaller tasks. These
smaller tasks are easier to work with and keep the details of their operation from the other parts of
the program that do not need to know them. This makes programs easier to understand and easier
to maintain.
A procedure in GAUSS is basically a user-defined function that can be used as if it were an
intrinsic part of the language. A procedure can be as small and simple or as large and complicated
as necessary to perform a particular task. Procedures allow you to build on your previous work
and on the work of others rather than starting over again and again to perform related tasks.
Any intrinsic command or function may be used in a procedure, as well as any user-defined
function or other procedure. Procedures can refer to any global variable; that is, any variable in the
global symbol table that can be shown with the show command. It is also possible to declare local
variables within a procedure. These variables are known only inside the procedure they are defined
in and cannot be accessed from other procedures or from the main level program code.
All labels and subroutines inside a procedure are local to that procedure and will not be confused
with labels of the same name in other procedures.
8-1
Procedures
Procedures and Keywords
GAUSS User Guide
8.1
Defining a Procedure
A procedure definition consists of five parts, four of which are denoted by explicit GAUSS
commands:
1.
2.
3.
4.
5.
Procedure declaration
Local variable declaration
Body of procedure
Return from procedure
End of procedure definition
proc statement
local statement
retp statement
endp statement
There is always one proc statement and one endp statement in a procedure definition. Any
statements that come between these two statements are part of the procedure. Procedure
definitions cannot be nested. local and retp statements are optional. There can be multiple
local and retp statements in a procedure definition. Here is an example:
proc (3) = regress(x, y);
local xxi,b,ymxb,sse,sd,t;
xxi = invpd(x’x);
b = xxi * (x’y);
ymxb = y-xb;
sse = ymxb’ymxb/(rows(x)-cols(x));
sd = sqrt(diag(sse*xxi));
t = b./sd;
retp(b,sd,t);
endp;
This could be used as a function that takes two matrix arguments and returns three matrices as a
result. For example: is:
{ b,sd,t } = regress(x,y);
Following is a discussion of the five parts of a procedure definition.
8-2
Procedures and Keywords
8.1.1
Procedure Declaration
The proc statement is the procedure declaration statement. The format is:
rets
Optional constant, number of values returned by the procedure. Acceptable values here
are 0-1023; the default is 1.
name
Name of the procedure, up to 32 alphanumeric characters or an underscore, beginning
with an alpha or an underscore.
arg#
Names that will be used inside the procedure for the arguments that are passed to the
procedure when it is called. There can be 0-1023 arguments. These names will be
known only in the procedure being defined. Other procedures can use the same names,
but they will be separate entities.
8.1.2
Local Variable Declarations
The local statement is used to declare local variables. Local variables are variables known only
to the procedure being defined. The names used in the argument list of the proc statement are
always local. The format of the local statement is:
local x,y,f :proc,g:fn,z,h:keyword;
Local variables can be matrices or strings. If :proc, :fn, or :keyword follows the variable name
in the local statement, the compiler will treat the symbol as if it were a procedure, function, or
keyword respectively. This allows passing procedures, functions, and keywords to other
procedures. (For more information, see P P  P, Section 8.4.
Variables that are global to the system (that is, variables listed in the global symbol table that can
be shown with the show command) can be accessed by any procedure without any redundant
declaration inside the procedure. If you want to create variables known only to the procedure
8-3
Procedures
proc [[(rets) =]] name([[arg1,arg2,...argN]]);
GAUSS User Guide
being defined, the names of these local variables must be listed in a local statement. Once a
variable name is encountered in a local statement, further references to that name inside the
procedure will be to the local rather than to a global having the same name. (See clearg, varget,
and varput in the GAUSS L R for ways of accessing globals from within
procedures that have locals with the same name.)
The local statement does not initialize (set to a value) the local variables. If they are not passed
in as parameters, they must be assigned some value before they are accessed or the program will
terminate with a Variable not initialized error message.
All local and global variables are dynamically allocated and sized automatically during execution.
Local variables, including those that were passed as parameters, can change in size during the
execution of the procedure.
Local variables exist only when the procedure is executing and then disappear. Local variables
cannot be listed with the show command.
The maximum number of locals is limited by stack space and the size of workspace memory. The
limiting factor applies to the total number of active local symbols at any one time during
execution. If cat has 10 locals and it calls dog which has 20 locals, there are 30 active locals
whenever cat is called.
There can be multiple local statements in a procedure. They will affect only the code in the
procedure that follows. Therefore, for example, it is possible to refer to a global x in a procedure
and follow that with a local statement that declares a local x. All subsequent references to x
would be to the local x. (This is not good programming practice, but it demonstrates the principle
that the local statement affects only the code that is physically below it in the procedure
definition.) Another example is a symbol that is declared as a local and then declared as a local
procedure or function later in the same procedure definition. This allows doing arithmetic on local
function pointers before calling them. (For more information, see I P, Section
8.5.
8.1.3
Body of Procedure
The body of the procedure can have any GAUSS statements necessary to perform the task the
procedure is being written for. Other user-defined functions and other procedures can be
referenced as well as any global matrices and strings.
8-4
Procedures and Keywords
GAUSS procedures are recursive, so the procedure can call itself as long as there is logic in the
procedure to prevent an infinite recursion. The process would otherwise terminate with either an
Insufficient workspace memory message or a Procedure calls too deep message,
depending on the space necessary to store the locals for each separate invocation of the procedure.
Procedures
8.1.4
Returning from the Procedure
The return from the procedure is accomplished with the retp statement:
retp;
retp(expression1,expression2,. . .,expressionN);
The retp statement can have multiple arguments. The number of items returned must coincide
with the number of rets in the proc statement.
If the procedure was defined with no items returned, the retp statement is optional. The endp
statement that ends the procedure will generate an implicit retp with no objects returned. If the
procedure returns one or more objects, there must be an explicit retp statement.
There can be multiple retp statements in a procedure, and they can be anywhere inside the body
of the procedure.
8.1.5
End of Procedure Definition
The endp statement marks the end of the procedure definition:
endp;
An implicit retp statement that returns nothing is always generated here so it is impossible to run
off the end of a procedure without returning. If the procedure was defined to return one or more
objects, executing this implicit return will result in a Wrong number of returns error message
and the program will terminate.
8-5
GAUSS User Guide
8.2
Calling a Procedure
Procedures are called like this:
dog(i,j,k);
/* no returns */
y = cat(i,j,k);
/* one return */
{ x,y,z } = bat(i,j,k);
/* multiple returns */
call bat(i,j,k);
/* ignore any returns */
Procedures are called in the same way that intrinsic functions are called. The procedure name is
followed by a list of arguments in parentheses. The arguments must be separated by commas.
If there is to be no return value, use
proc (0) = dog(x,y,z);
when defining the procedure and use
dog(ak,4,3);
or
call dog(ak,4,3);
when calling it.
The arguments passed to procedures can be complicated expressions involving calls to other
functions and procedures. This calling mechanism is completely general. For example,
8-6
Procedures and Keywords
y = dog(cat(3*x,bird(x,y))-2,2,1);
is legal.
Procedures
8.3
Keywords
A keyword, like a procedure, is a subroutine that can be called interactively or from within a
GAUSS program. A keyword differs from a procedure in that a keyword accepts exactly one
string argument, and returns nothing. Keywords can perform many tasks not as easily
accomplished with procedures.
8.3.1
Defining a Keyword
A keyword definition is much like a procedure definition. Keywords always are defined with 0
returns and 1 argument. The beginning of a keyword definition is the keyword statement:
keyword name(strarg);
name
Name of the keyword, up to 32 alphanumeric characters or an underscore, beginning
with an alpha or an underscore.
strarg
Name that will be used inside of the keyword for the argument that is passed to the
keyword when it is called. There is always one argument. The name is known only in
the keyword being defined. Other keywords can use the same name, but they will be
separate entities. This will always be a string. If the keyword is called with no
characters following the name of the keyword, this will be a null string.
The rest of the keyword definition is the same as a procedure definition. (For more information,
see D  P, Section 8.1. Keywords always return nothing. Any retp statements, if
used, should be empty. For example:
8-7
GAUSS User Guide
keyword add(s);
local tok, sum;
if s $=\,= "";
print "The argument is a null string";
retp;
endif;
print "The argument is: ’" s "’";
sum = 0;
do until s $=\,= "";
{ tok, s } = token(s);
sum = sum + stof(tok);
endo;
format /rd 1,2;
print "The sum is:
" sum;
endp;
The keyword defined above will print the string argument passed to it. The argument will be
printed enclosed in single quotes.
8.3.2
Calling a Keyword
When a keyword is called, every character up to the end of the statement, excluding the leading
spaces, is passed to the keyword as one string argument. For example, if you type
add 1 2 3 4 5;
the keyword will respond
The sum is:
8-8
15.00
Procedures and Keywords
Here is another example:
add;
Procedures
the keyword will respond
The argument is a null string
8.4
Passing Procedures to Procedures
Procedures and functions can be passed to procedures in the following way:
proc max(x,y); /* procedure to return maximum */
if x>y;
retp(x);
else;
retp(y);
endif;
endp;
proc min(x,y); /* procedure to return minimum */
if x<y;
retp(x);
else;
retp(y);
endif;
endp;
fn lgsqrt(x) = ln(sqrt(x));
/* function to return
:: log of square root
*/
8-9
GAUSS User Guide
proc myproc(&f1,&f2,x,y);
local f1:proc, f2:fn, z;
z = f1(x,y);
retp(f2(z));
endp;
The procedure myproc takes four arguments. The first is a procedure f1 that has two arguments.
The second is a function f2 that has one argument. It also has two other arguments that must be
matrices or scalars. In the local statement, f1 is declared to be a procedure and f2 is declared to
be a function. They can be used inside the procedure in the usual way. f1 will be interpreted as a
procedure inside myproc, and f2 will be interpreted as a function. The call to myproc is made as
follows:
k = myproc(&max,&lgsqrt,5,7);
/* log of square root of 7 */
k = myproc(&min,&lgsqrt,5,7);
/* log of square root of 5 */
The ampersand (&) in front of the function or procedure name in the call to myproc causes a
pointer to the function or procedure to be passed. No argument list should follow the name when it
is preceded by the ampersand.
Inside myproc, the symbol that is declared as a procedure in the local statement is assumed to
contain a pointer to a procedure. It can be called exactly like a procedure is called. It cannot be
save’d but it can be passed on to another procedure. If it is to be passed on to another procedure,
use the ampersand in the same way.
8.5
Indexing Procedures
This example assumes there are a set of procedures named f1-f5 that are already defined. A 1×5
vector procvec is defined by horizontally concatenating pointers to these procedures. A new
procedure, g(x,i) is then defined to return the value of the ith procedure evaluated at x:
procvec = &f1 ˜ &f2 ˜ &f3 ˜ &f4 ˜ &f5;
8-10
Procedures and Keywords
Procedures
proc g(x,i);
local f;
f = procvec[i];
local f:proc;
retp( f(x) );
endp;
The local statement is used twice. The first time, f is declared to be a local matrix. After f has
been set equal to the ith pointer, f is declared to be a procedure and is called as a procedure in the
retp statement.
8.6
Multiple Returns from Procedures
Procedures can return multiple items, up to 1023. The procedure is defined like this example of a
complex inverse:
proc (2) = cminv(xr,xi); /* (2) specifies number of
:: return values
*/
local ixy, zr, zi;
ixy = inv(xr)*xi;
zr = inv(xr+xi*ixy); /* real part of inverse. */
zi = -ixy*zr;
/* imaginary part of inverse. */
retp(zr,zi);
/* return: real part, imaginary part */
endp;
It can then be called like this:
{ zr,zi } = cminv(xr,xi);
To make the assignment, the list of targets must be enclosed in braces.
8-11
GAUSS User Guide
Also, a procedure that returns more than one argument can be used as input to another procedure
or function that takes more than one argument:
proc (2) = cminv(xr,xi);
local ixy, zr, zi;
ixy = inv(xr)*xi;
zr = inv(xr+xi*ixy);
zi = -ixy*zr;
retp(zr,zi);
endp;
/* real part of inverse. */
/* imaginary part of inverse. */
proc (2) = cmmult(xr,xi,yr,yi);
local zr,zi;
zr = xr*yr-xi*yi;
zi = xr*yi+xi*yr;
retp(zr,zi);
endp;
{ zr,zi } = cminv( cmmult(xr,xi,yr,yi) );
The two returned matrices from cmmult() are passed directly to cminv() in the statement above.
This is equivalent to the following statements:
{ tr,ti } = cmmult(xr,xi,yr,yi);
{ zr,zi } = cminv(tr,ti);
This is completely general so the following program is legal:
proc (2) = cmcplx(x);
local r,c;
r = rows(x);
c = cols(x);
retp(x,zeros(r,c));
endp;
8-12
Procedures and Keywords
/* real part of inverse. */
/* imaginary part of inverse. */
Procedures
proc (2) = cminv(xr,xi);
local ixy, zr, zi;
ixy = inv(xr)*xi;
zr = inv(xr+xi*ixy);
zi = -ixy*zr;
retp(zr,zi);
endp;
proc (2) = cmmult(xr,xi,yr,yi);
local zr,zi;
zr = xr*yr-xi*yi;
zi = xr*yi+xi*yr;
retp(zr,zi);
endp;
{ xr,xi } = cmcplx(rndn(3,3));
{ yr,yi } = cmcplx(rndn(3,3));
{ zr,zi } = cmmult( cminv(xr,xi),cminv(yr,yi) );
{ qr,qi } = cmmult( yr,yi,cminv(yr,yi) );
{ wr,wi } = cmmult(yr,yi,cminv(cmmult(cminv(xr,xi),yr,yi)));
8.7
Saving Compiled Procedures
When a file containing a procedure definition is run, the procedure is compiled and is then resident
in memory. The procedure can be called as if it were an intrinsic function. If the new command is
executed or you quit GAUSS and exit to the operating system, the compiled image of the
procedure disappears and the file containing the procedure definition will have to be compiled
again.
If a procedure contains no global references, that is, if it does not reference any global matrices or
strings and it does not call any user-defined functions or procedures, it can be saved to disk in
compiled form in a .fcg file with the save command, and loaded later with the loadp command
8-13
GAUSS User Guide
whenever it is needed. This will usually be faster than recompiling. For example:
save path = c:\gauss\cp proc1,proc2,proc3;
loadp path = c:\gauss\cp proc1,proc2,proc3;
The name of the file will be the same as the name of the procedure, with a .fcg extension. (For
details, see loadp and save in the GAUSS L R.)
All compiled procedures should be saved in the same subdirectory, so there is no question where
they are located when it is necessary to reload them. The loadp path can be set in your startup file
to reflect this. Then, to load in procedures, use
loadp proc1,proc2,proc3;
Procedures that are saved in .fcg files will NOT be automatically loaded. It is necessary to
explicitly load them with loadp. This feature should be used only when the time necessary for the
autoloader to compile the source is too great. Also, unless these procedures have been compiled
with #lineson, debugging will be more complicated.
8-14
Sparse Matrices
The sparse matrix data type stores only the non-zero values of a 2-dimensional sparse matrix,
which makes working with sparse matrices faster and more efficient.
9.1
Defining Sparse Matrices
The sparse matrix data type is strongly typed in GAUSS, which means that a variable must be
defined as a sparse matrix variable before it may be used as such. Once a variable has been defined
as a sparse matrix, it may not be used as another data type. Similarly, once a variable has been
used as a matrix, array, or other non-sparse data type, it may not be redefined as a sparse matrix.
To define a global sparse matrix, you may use either the declare or the let command:
declare sparse matrix sm1;
let sparse matrix sm1;
9-1
Sparse
Matrices
9
GAUSS User Guide
or the following implicit let statement:
sparse matrix sm1;
declare may be used to define multiple sparse matrices in a single statement:
declare sparse matrix sm1, sm2, sm3;
To define a local sparse matrix inside of a procedure, use an implicit let statement:
sparse matrix lsm1;
As neither let nor declare support the initialization of a sparse matrix at this time, you must
initialize a sparse matrix with an assignment after defining it.
9.2
Creating and Using Sparse Matrices
Several new functions have been added to allow you to create and manipulate sparse matrices.
These functions are:
denseToSp
Converts a dense matrix to a sparse matrix.
denseToSpRE
Converts a dense matrix to a sparse matrix, using a relative epsilon.
packedToSp
Creates a sparse matrix from a packed matrix of non-zero values and
row and column indices.
spBiconjGradSol Solves the system of linear equations Ax=b using the biconjugate
gradient method.
spConjGradSol
9-2
Solves the system of linear equations Ax=b for symmetric matrices
using the conjugate gradient method.
Sparse Matrices
Creates a sparse matrix from vectors of non-zero values, row
indices, and column indices.
spDenseSubmat
Returns a dense submatrix of sparse matrix.
spDiagRvMat
Inserts submatrices along the diagonal of a sparse matrix.
spEigv
Computes a specified number of eigenvalues and eigenvectors of a
square, sparse matrix.
spEye
Creates a sparse identity matrix.
spGetNZE
Returns the non-zero values in a sparse matrix, as well as their
corresponding row and column indices.
spLDL
Computes the LDL decomposition of a symmetric sparse matrix.
spLU
Computes the LU decomposition of a sparse matrix with partial
pivoting.
spNumNZE
Returns the number of non-zero elements in a sparse matrix.
spOnes
Generates a sparse matrix containing only ones and zeros
spSubmat
Returns a sparse submatrix of sparse matrix.
spToDense
Converts a sparse matrix to a dense matrix.
spTrTDense
Multiplies a sparse matrix transposed by a dense matrix.
spTScalar
Multiplies a sparse matrix by a scalar.
spZeros
Creates a sparse matrix containing no non-zero values.
See C R, Chapter 29, for detailed information on each command.
9.3
Sparse Support in Matrix Functions and Operators
Support for the sparse matrix data type has also been added to many matrix functions and
operators. The following is a complete list of the matrix functions and operators that currently
support the new sparse matrix type:
9-3
Sparse
Matrices
spCreate
GAUSS User Guide
9-4
Sparse Matrices
0
∼
|
*
.*
+
/
./
/=
./=
==
.= =
>
.>
>=
.>=
<
.<
<=
.<=
abs
cols
maxc
minc
print
rows
scalerr
show
type
Sparse
Matrices
Indexing is also supported for sparse matrices, using the same syntax as matrix indexing.
Note that printing a sparse matrix results in a table of the non-zero values contained in the sparse
matrix, followed by their corresponding row and column indices, respectively.
9.3.1
Return Types for Dyadic Operators
The types of the returns for the dyadic operators were decided on a case-by-case basis, using the
following general principles:
1. The return type for dyadic operations on two dense arguments is always dense.
2. The return type for dyadic operations on two sparse arguments is always sparse unless the
result is likely to be significantly less sparse than the sparse arguments.
3. The return type for dyadic operations on a dense argument and a sparse argument (regardless
of order) is dense unless the return is likely to be at least as sparse as the sparse argument.
These general principles have led to the following decisions regarding return types (note that only
the cases that are displayed in these tables have been implemented at this point):
9-5
GAUSS User Guide
Element-by-Element Numeric Operators
Element-by-Element Addition
Result =
Left
Operator Right
dense = sparse
+
dense
dense = dense
+
dense
sparse = sparse
+
sparse
dense = dense
+
sparse
Element-by-Element Subtraction
Result =
Left
Operator Right
dense = sparse
dense
dense = dense
dense
sparse = sparse
sparse
dense = dense
sparse
Element-by-Element Multiplication
Result =
Left
Operator Right
sparse = sparse
.*
dense
dense = dense
.*
dense
sparse = sparse
.*
sparse
sparse = dense
.*
sparse
Element-by-Element Division
Result =
Left
Operator Right
sparse = sparse
./
dense
dense = dense
./
dense
dense = sparse
./
sparse
dense = dense
./
sparse
9-6
Sparse Matrices
Other Numeric Operators
Matrix Multiplication
=
Left
Operator
= sparse
*
= dense
*
= sparse
*
Right
dense
dense
sparse
Result
dense
dense
Linear Solve
Left Operator
dense
/
dense
/
Right
dense
sparse
=
=
=
Sparse
Matrices
Result
dense
dense
sparse
Note that at this time, the dense = dense / sparse case is defined only for real data.
When either of its arguments are sparse, the / operator uses a tolerance to determine the result,
which may be read or set using the sysstate function, case 39. The default tolerance is 1e-14.
Relational Operators
Since the results of element-by-element ’dot’ comparison operators depend largely on the kind of
data inputted, there are both both dense-returning and sparse-returning versions of the dot
comparison operators when one or both arguments is a sparse matrix. The regular dot comparison
operators and their alphabetic counterparts always return dense matrices, and there is a new set of
alphabetic dot comparison operators that all return sparse matrices:
Element-by-Element Dot Comparison Operators
Operation
Dense-Returning Sparse-Returning
Equal to
.= =
.eq
.speq
Not equal to
./=
.ne
.spne
Less than
.<
.lt
.splt
Less than or equal to
.<=
.le
.sple
Greater than
.>
.gt
.spgt
Greater than or equal to .>=
.ge
.spge
9-7
GAUSS User Guide
Since the element-by-element ’non-dot’ comparison operators (= =, /=, <, <=, >, >=) and their
alphabetic counterparts (eq, ne, lt, le, gt, ge) all return scalars, there are no sparse-returning
versions of them.
Other Matrix Operators
9-8
Result
dense
sparse
Horizontal Concatenation
=
Left
Operator Right
= dense
∼
dense
= sparse
∼
sparse
Result
dense
sparse
Vertical Concatenation
=
Left
Operator Right
= dense
|
dense
= sparse
|
sparse
N-Dimensional Arrays
10
[1, 1] [1, 2] [2, 1] [2, 2] [3, 1] [3, 2]
The slowest moving dimension in memory is indexed on the right, and the fastest moving
dimension is indexed on the left. This is true of N-dimensional arrays as well. A 4×3×2 array is
stored in the following way:
[1, 1, 1]
[2, 1, 1]
[3, 1, 1]
[4, 1, 1]
[1, 1, 2]
[2, 1, 2]
[3, 1, 2]
[4, 1, 2]
[1, 2, 1]
[2, 2, 1]
[3, 2, 1]
[4, 2, 1]
[1, 2, 2]
[2, 2, 2]
[3, 2, 2]
[4, 2, 2]
[1, 3, 1]
[2, 3, 1]
[3, 3, 1]
[4, 3, 1]
[1, 3, 2]
[2, 3, 2]
[3, 3, 2]
[4, 3, 2]
A complex N-dimensional array is stored in memory in the same way. Like complex matrices,
complex arrays are stored with the entire real part first, followed by the entire imaginary part.
10-1
Arrays
In GAUSS, internally, matrices and arrays are separate data types. Matrices, which are
2-dimensional objects, are stored in memory in row major order. Therefore, a 3×2 matrix is stored
as follows:
GAUSS User Guide
Every N-dimensional array has a corresponding N×1 vector of orders that contains the sizes of
each dimension of the array. This is stored with the array and can be accessed with getorders.
The first element of the vector of orders corresponds to the slowest moving dimension, and the last
element corresponds to the fastest moving dimension (refer to the sectionnameGlossary of Terms
at the end of the chapter for clear definitions of these terms). The vector of orders for a
6×5×4×3×2 array, which has 5 dimensions, is the following 5×1 vector:
6
5
4
3
2
Two terms that are important in working with N-dimensional arrays are “dimension index” and
“dimension number.” A dimension index specifies a dimension based on indexing the vector of
orders. It is a scalar, 1-to-N, where 1 corresponds to the dimension indicated by the first element
of the vector of orders of the array (the slowest moving dimension) and N corresponds to the
dimension indicated by the last element of the vector of orders (the fastest moving dimension).
A dimension number specifies dimensions by numbering them in the same order that one would
add dimensions to an array. In other words, the dimensions of an N-dimensional array are
numbered such that the fastest moving dimension has a dimension number of 1, and the slowest
moving dimension has a dimension number of N.
A 6×5×4×3×2 array has 5 dimensions, so the first element of the vector of orders (in this case, 6)
refers to the size of dimension number 5. Since the index of this element in the vector of orders is
1, the dimension index of the corresponding dimension (dimension number 5) is also 1.
You will find references to both dimension index and dimension number in the documentation for
the functions that manipulate arrays.
There are a number of functions that have been designed to manipulate arrays. These functions
allow you to manipulate a subarray within the array by passing in a locator vector to index any
subarray that comprises a contiguous block of memory within the larger block. A vector of indices
of an N-dimensional array is a [1-to-N]×1 vector of base 1 indices into the array, where the first
element corresponds to the first element in a vector of orders. An N×1 vector of indices locates the
10-2
N-Dimensional Arrays
scalar whose position is indicated by the indices. For a 4×3×2 array x, the 3×1 vector of indices:
3
2
1
indexes the [3,2,1] element of x. A 2×1 vector of indices for this 3-dimensional example,
references the 1-dimensional array whose starting location is given by the indices.
Because the elements of the vector of indices are always in the same order (the first element of the
vector of indices corresponds to the slowest moving dimension of the array, the second element to
the second slowest moving dimension, and so on), each unique vector of indices locates a unique
subarray.
Arrays
In general, an [N-K]×1 vector of indices locates a K-dimensional subarray that begins at the
position indicated by the indices. The sizes of the dimensions of the K-dimensional subarray
correspond to the last K elements of the vector of orders of the N-dimensional array. For a
6×5×4×3×2 array y, the 2×1 vector of indices:
2
5
locates the 4×3×2 subarray in y that begins at [2,5,1,1,1] and ends at [2,5,4,3,2].
10.1
Bracketed Indexing
Brackets ‘[ ]’ can be used to index N-dimensional arrays in virtually the same way that they are
used to index matrices. Bracketed indexing is slower than the convenience array functions, such as
getarray and setarray; however, it can be used to index non-contiguous elements. In order to
index an N-dimensional array with brackets, there must be N indices located within the brackets,
where the first index corresponds to the slowest moving dimension of the array and the last index
corresponds to the fastest moving dimension.
10-3
GAUSS User Guide
For a 2×3×4 array x, such that
[1,1,1] through [1,3,4] =
1 2 3 4
5 6 7 8
9 10 11 12
[2,1,1] through [2,3,4] =
13 14 15 16
17 18 19 20
21 22 23 24
x[1,2,3] returns a 1×1×1 array containing the [1,2,3] element of x:
7
x[.,3,2] returns a 2×1×1 array containing
10
22
x[2,.,1 4] returns a 1×3×2 array containing
13 16
17 20
21 24
10-4
N-Dimensional Arrays
x[.,2,1:3] returns a 2×1×3 array containing
5
6
7
17 18 19
10.2
E×E Conformability
The following describes rules for E×E conformability of arrays for operators and functions with
two or more arguments.
• Any N-dimensional array is conformable to a scalar.
• Two arrays are E×E conformable if they comply with one of the following requirements:
– The two arrays have the same number of dimensions, and each dimension has the same
size.
– The two arrays have the same number of dimensions, and each of the N-2 slowest
moving dimensions has the same size. In this case, the 2 fastest moving dimensions of
the arrays must follow the E×E comformability rules that apply to matrices.
– Both of the arrays have fewer than 3 dimensions, and they follow the E×E
conformability rules that apply to matrices.
10.3
Glossary of Terms
dimensions The number of dimensions of an object.
vector of orders N×1 vector of the sizes of the dimensions of an object, where N is the
number of dimensions, and the first element corresponds to the slowest moving
dimension.
10-5
Arrays
• An array is conformable to a matrix only if the array has fewer than 3 dimensions, and the
array and matrix follow the standard rules of E×E conformability.
GAUSS User Guide
vector of indices [1-to-N]×1 vector of indices into an array, where the first element
corresponds to the first element in a vector of orders.
dimension number Scalar [1-to-N], where 1 corresponds to the fastest moving dimension
and N to the slowest moving dimension.
dimension index Scalar [1-to-N], where 1 corresponds to the first element of the vector of
orders or vector of indices.
locator [1-to-N]×1 vector of indices into an array used by array functions to locate a
contiguous block of the array.
10-6
Working with Arrays
11.1
11
Initializing Arrays
The term “arrays” specifically refers to N-dimensional arrays and must not be confused with
matrices. Matrices and arrays are distinct types even if in fact they contain identical information.
Functions for conversion from one to the other are described below.
There are five basic ways of creating an array depending on how the contents are specified:
areshape
Create array from specified matrix .
aconcat
Create array from matrices and arrays.
aeye
Create array of identity matrices.
11-1
Working
with Arrays
The use of N-dimensional arrays in GAUSS is an additional tool for reducing development time
and increasing execution speed of programs. There are multiple ways of handling N-dimensional
arrays and using them to solve problems, and these ways sometimes have implications for a
trade-off between speed of execution and development time. We will try to make this clear in this
chapter.
GAUSS User Guide
arrayinit
Allocate array filled with specified scalar value.
arrayalloc
Allocate array with no specified contents.
11.1.1
areshape
areshape is a method for creating an array with specified contents. arrayinit creates an array
filled with a selected scalar value: areshape will do the same, but with a matrix. For example,
given a matrix, areshape will create an array containing multiple copies of that matrix:
x = reshape(seqa(1,1,4),2,2);
ord = 3 | 2 | 2;
a = areshape(x,ord);
print a;
Plane [1,.,.]
1.0000 2.0000
3.0000 4.0000
Plane [2,.,.]
1.0000 2.0000
3.0000 4.0000
Plane [3,.,.]
1.0000 2.0000
3.0000 4.0000
Reading Data from the Disk into an Array
areshape is a fast way to re-dimension a matrix or array already in memory. For example,
suppose we have a GAUSS data set containing panel data and that it’s small enough to be read in
all at once:
11-2
Working with Arrays
panel = areshape(loadd("panel"),5|100|10);
mn = amean(panel,2); /* 5x1x10 array of means */
/*of each panel */
mm = moment(panel,0); /* 5x10x10 array of moments */
/* of each panel */
/*
** vc is a 5x10x10 array of
** covariance matrices
*/
vc = mm / 100 - amult(atranspose(mn,1|3|2),mn);
panel is a 5×100×10 array, and in this context is 5 panels of 100 cases measured on 10 variables.
Inserting Random Numbers into Arrays
A random array of any dimension or size can be quickly created using areshape. Thus, for a
10×10×5×3 array:
The quick and dirty method above uses the linear congruential generator, which is fast but doesn’t
have the properties required for serious Monte Carlo work. For series simulation you will need to
use the KM generator:
sd0 = 345678;
ord = { 10, 10, 5, 3 };
{ z,sd0 } = rndKMu(prodc(ord),1,sd0);
y = areshape(z,ord);
11-3
Working
with Arrays
ord = { 10, 10, 5, 3 };
y = areshape(rndu(prodc(ord),1),ord);
GAUSS User Guide
Expanding a Matrix into an Array Vector of Matrices
For computing the log-likelihood of a variance components model of panel data, it is necessary to
expand a T×T matrix into an NT×T array of these matrices. This is easily accomplished using
areshape. For example:
m = { 1.0 0.3 0.2,
0.3 1.0 0.1,
0.2 0.1 1.0 };
r = areshape(m,3|3|3);
print r;
Plane [1,.,.]
1.0000
0.3000
0.2000
0.3000
1.0000
0.1000
0.2000
0.1000
1.0000
Plane [2,.,.]
1.0000
0.3000
0.2000
0.3000
1.0000
0.1000
0.2000
0.1000
1.0000
Plane [3,.,.]
1.0000
0.3000
0.2000
11.1.2
0.3000
1.0000
0.1000
0.2000
0.1000
1.0000
aconcat
aconcat creates arrays from conformable sets of matrices or arrays. With this function, contents
are completely specified by the user. This example tries three concatenations, one along each
11-4
Working with Arrays
dimension:
rndseed 345678;
x1 = rndn(2,2);
x2 = arrayinit(2|2,1);
/*
** along the first dimension or rows
*/
a = aconcat(x1,x2,1);
print a;
-0.4300 -0.2878 1.0000 1.0000
-0.1327 -0.0573 1.0000 1.0000
/*
** along the second dimension or columns
*/
a = aconcat(x1,x2,2);
print a;
Working
with Arrays
-0.4300 -0.2878
-0.1327 -0.0573
1.0000 1.0000
1.0000 1.0000
/*
** along the third dimension
*/
a = aconcat(x1,x2,3);
print a;
Plane [1,.,.]
11-5
GAUSS User Guide
-0.4300 -0.2878
-0.1327 -0.0573
Plane [2,.,.]
1.0000 1.0000
1.0000 1.0000
11.1.3
aeye
aeye creates an array in which the principal diagonal of the two trailing dimensions is set to one.
For example:
ord = 2 | 3 | 3;
a = aeye(ord);
print a;
Plane [1,.,.]
1.00000 0.00000 0.00000
0.00000 1.00000 0.00000
0.00000 0.00000 1.00000
Plane [2,.,.]
1.00000 0.00000 0.00000
0.00000 1.00000 0.00000
0.00000 0.00000 1.00000
11.1.4
arrayinit
arrayinit creates an array with all elements set to a specified value. For example:
ord = 3 | 2 | 3;
11-6
Working with Arrays
a = arrayinit(ord,1);
print a;
Plane [1,.,.]
1.0000 1.0000 1.0000
1.0000 1.0000 1.0000
Plane [2,.,.]
1.0000 1.0000 1.0000
1.0000 1.0000 1.0000
Plane [3,.,.]
1.0000 1.0000 1.0000
1.0000 1.0000 1.0000
11.1.5
arrayalloc
For example, to allocate a 2×2×3 array:
rndseed 345678;
ord = 3 | 2 | 2;
a = arrayalloc(ord,0);
for i(1,ord[1],1);
a[i,.,.] = rndn(2,3);
endfor;
11-7
Working
with Arrays
arrayalloc creates an array with specified number and size of dimensions without setting
elements to any values. This requires a vector specifying the order of the array. The length of the
vector determines the number of dimensions, and each element determines the size of the
corresponding dimensions. The array will then have to be filled using any of several methods
described later in this chapter.
GAUSS User Guide
print a;
Plane [1,.,.]
-0.4300 -0.2878 -0.1327
-0.0573 -1.2900 0.2467
Plane [2,.,.]
-1.4249 -0.0796 1.2693
-0.7530 -1.7906 -0.6103
Plane [3,.,.]
1.2586 -0.4773 0.7044
-1.2544 0.5002 0.3559
The second argument in the call to arrayalloc specifies whether the created array is real or
complex. arrayinit creates only real arrays.
11.2
Assigning to Arrays
There are three methods used for assignment to an array:
index operator
The same method as matrices, generalized to arrays.
putArray
Put a subarray into an N-dimensional array and returns the result.
setArray
Set a subarray of an N-dimensional array in place.
And there are several ways to extract parts of arrays:
index operator
11-8
The same method as matrices, generalized to arrays.
Working with Arrays
getArray
Get a subarray from an array.
getMatrix
Get a matrix from an array.
getMatrix4D
Get a matrix from a 4-dimensional array.
getScalar4D
Get a scalar from a 4-dimensional array.
The index operator is the slowest way to extract parts of arrays. The specialized functions are the
fastest when the circumstances are appropriate for their use.
11.2.1
index operator
The index operator will put a subarray into an array in a manner analogous to the use of index
operators on matrices:
a = arrayinit(3|2|2,0);
b = arrayinit(3|1|2,1);
a[.,2,.] = b;
print a;
Plane [1,.,.]
Working
with Arrays
0.00000 0.00000
1.0000 1.0000
Plane [2,.,.]
0.00000 0.00000
1.0000 1.0000
Plane [3,.,.]
0.00000 0.00000
1.0000 1.0000
11-9
GAUSS User Guide
As this example illustrates, the assignment doesn’t have to be contiguous. putMatrix and
setMatrix require a contiguous assignment, but for that reason they are faster.
The right hand side of the assignment can also be a matrix:
a[1,.,.] = rndn(2,2);
print a;
Plane [1,.,.]
-1.7906502 -0.61038103
1.2586160 -0.47736360
Plane [2,.,.]
0.00000 0.00000
1.00000 1.00000
Plane [3,.,.]
0.00000 0.00000
1.00000 1.00000
The index operator will extract an array from a subarray in a manner analogous to the use of index
operators on matrices:
a = areshape(seqa(1,1,12),3|2|2);
b = a[.,1,.];
print a;
Plane [1,.,.]
1.0000 2.0000
3.0000 4.0000
11-10
Working with Arrays
Plane [2,.,.]
5.0000 6.0000
7.0000 8.0000
Plane [3,.,.]
9.0000 10.000
11.000 12.000
print b;
Plane [1,.,.]
1.0000 2.0000
Plane [2,.,.]
5.0000 6.0000
Plane [3,.,.]
Working
with Arrays
9.0000 10.000
It is important to note that the result is always an array even if it’s a scalar value:
c = a[1,1,1];
print c;
Plane [1,.,.]
1.0000
11-11
GAUSS User Guide
If you require a matrix result, and if the result has one or two dimensions, use arraytomat to
convert to a matrix, or use getMatrix, or getMatrix4D. Or, if the result is a scalar, use
getScalar3D or getScalar4D.
11.2.2
getArray
getArray is an additional method for extracting arrays:
a = areshape(seqa(1,1,12),3|2|2);
b = getarray(a,2|1);
print a;
Plane [1,.,.]
1.0000 2.0000
3.0000 4.0000
Plane [2,.,.]
5.0000 6.0000
7.0000 8.0000
Plane [3,.,.]
9.0000 10.000
11.000 12.000
print b;
5.0000 6.0000
getArray can only extract a contiguous part of an array. To get non-contiguous parts you must
use the index operator.
11-12
Working with Arrays
11.2.3
getMatrix
If the result is one or two dimensions, getMatrix returns a portion of an array converted to a
matrix. getMatrix is about 20 percent faster than the index operator:
a = areshape(seqa(1,1,12),3|2|2);
b = getMatrix(a,2);
print b;
5.0000 6.0000
7.0000 8.0000
11.2.4
getMatrix4D
This is a specialized version of getMatrix for 4-dimensional arrays. It behaves just like
getMatrix but is dramatically faster for that type of array. The following illustrates the difference
in timing:
a = arrayinit(100|100|10|10,1);
t0 = date;
Working
with Arrays
for i(1,100,1);
for j(1,100,1);
b = a[i,j,.,.];
endfor;
endfor;
t1 = date;
e1 = ethsec(t0,t1);
print e1;
print;
t2=date;
for i(1,100,1);
11-13
GAUSS User Guide
for j(1,100,1);
b = getMatrix4d(a,i,j);
endfor;
endfor;
t3 = date;
e2 = ethsec(t2,t3);
print e2;
print;
print ftostrC(100*((e1-e2)/e1),
"percent difference - %6.2lf%%");
13.000000
5.0000000
percent difference - 61.54%
11.2.5
getScalar3D, getScalar4D
These are specialized versions of getMatrix for retrieving scalar elements of 3-dimensional and
4-dimensional arrays, respectively. They behave just like getMatrix, with scalar results, but are
much faster. For example:
a = arrayinit(100|10|10,1);
t0 = date;
for i(1,100,1);
for j(1,10,1);
for k(1,10,1);
b = a[i,j,k];
endfor;
endfor;
endfor;
11-14
Working with Arrays
t1 = date;
e1 = ethsec(t0,t1);
print e1;
print;
t2=date;
for i(1,100,1);
for j(1,10,1);
for k(1,10,1);
b = getscalar3d(a,i,j,k);
endfor;
endfor;
endfor;
t3 = date;
e2 = ethsec(t2,t3);
print e2;
print;
print ftostrC(100*((e1-e2)/e1),
"percent difference - %6.2lf%%");
7.0000000
2.0000000
Working
with Arrays
percent difference - 71.43%
11.2.6
putArray
putArray enters a subarray, matrix, or scalar into an N-dimensional array and returns the result in
an array. This function is much faster than the index operator, but it requires the part of the array
being assigned to be contiguous:
a = arrayinit(3|2|2,3);
b = putarray(a,2,eye(2));
11-15
GAUSS User Guide
print b;
Plane [1,.,.]
3.0000 3.0000
3.0000 3.0000
Plane [2,.,.]
1.0000 0.00000
0.00000 1.0000
Plane [3,.,.]
3.0000 3.0000
3.0000 3.0000
11.2.7
setArray
setArray enters a subarray, matrix, or scalar into an N-dimensional array in place:
a = arrayinit(3|2|2,3);
setarray a,2,eye(2);
print b;
Plane [1,.,.]
3.0000 3.0000
3.0000 3.0000
Plane [2,.,.]
1.0000 0.0000
0.0000 1.0000
11-16
Working with Arrays
Plane [3,.,.]
3.0000 3.0000
3.0000 3.0000
11.3
Looping with Arrays
When working with arrays, for loops and do loops may be used in the usual way. In the
following, let Y be an N×1×L array of L time series, X an N×1×K array of K independent
variables, B a K×L matrix of regression coefficients, phi a P×L×L array of garch coefficients,
theta a Q×L×L array of arch coefficients, and omega a L×L symmetric matrix of constants. The
log-likelihood for a multivariate garch BEKK model can be computed using the index operator:
yord
xord
gord
aord
=
=
=
=
getOrders(Y);
getOrders(X);
getOrders(phi);
getOrders(theta);
No. of observations */
No. of time series */
No. of independent variables */
in mean equation */
order of garch parameters */
order of arch parameters */
Working
with Arrays
N = yord[1]; /*
L = yord[3]; /*
K = xord[3]; /*
/*
P = gord[1]; /*
Q = aord[1]; /*
r = maxc(P|Q);
E = Y - amult(X,areshape(B,N|K|L));
sigma = areshape(omega,N|L|L);
for i(r+1,N,1);
for j(1,Q,1);
W = amult(theta[j,.,.],
atranspose(E[i-j,.,.],1|3|2));
sigma[i,.,.] = sigma[i,.,.] + amult(W,atranspose(W,1|3|2));
11-17
GAUSS User Guide
endfor;
for j(1,P,1);
sigma[i,.,.] = sigma[i,.,.] + amult(amult(phi[j,.,.],
sigma[i-j,.,.]),phi[j,.,.]);
endfor;
endfor;
sigmai = invpd(sigma);
lndet = ln(det(sigma));
lnl = -0.5*( L*(N-R)*asum(ln(det(sigmai)),1) +
asum(amult(amult(E,sigmai),atranspose(E,1|3|2)),3);
Instead of index operators, the above computation can be done using getArray and setArray:
yord
xord
gord
aord
=
=
=
=
getOrders(Y);
getOrders(X);
getOrders(phi);
getOrders(theta);
N = yord[1]; /*
L = yord[3]; /*
K = xord[3]; /*
/*
P = gord[1]; /*
Q = aord[1]; /*
No. of observations */
No. of time series */
No. of independent variables */
in mean equation */
order of garch parameters */
order of arch parameters */
r = maxc(P|Q);
E = Y - amult(X,areshape(B,N|K|L));
sigma = areshape(omega,N|L|L);
for i(r+1,N,1);
for j(1,Q,1);
W = amult(getArray(theta,j),
atranspose(getArray(E,i-j),2|1));
setarray sigma,i,getArray(sigma,i)+
11-18
Working with Arrays
amult(W,atranspose(W,2|1));
endfor;
for j(1,P,1);
setarray sigma,i,getArray(sigma,i)+
areshape(amult(amult(getArray(phi,j),
getArray(sigma,i-j)),getArray(phi,j)),3|3);
endfor;
endfor;
sigmai = invpd(sigma);
lndet = ln(det(sigma));
lnl = -0.5*( L*(N-R)*asum(ln(det(sigmai)),1)+
asum(amult(amult(E,sigmai),atranspose(E,1|3|2)),3)
Putting the two code fragments above into loops that called them a hundred times and measuring
the time, produced the following results:
index operator: 2.604 seconds
getArray, setArray: 1.092 seconds
Working
with Arrays
Thus, the getArray and setArray methods are more than twice as fast.
11.3.1
loopnextindex
Several keyword functions are available in GAUSS for looping with arrays. The problem in the
previous section, for example, can be written using these functions rather than with for loops:
sigind = r + 1;
sigloop:
11-19
GAUSS User Guide
sig0ind = sigind[1];
thetaind = 1;
thetaloop:
sig0ind = sig0ind - 1;
W = amult(getArray(theta,thetaind),
atranspose(getArray(E,sig0ind),2|1));
setarray sigma,sigind,getArray(sigma,sigind)+
amult(W,atranspose(W,2|1));
loopnextindex thetaloop,thetaind,aord;
sig0ind = sigind;
phiind = 1;
philoop:
sig0ind[1] = sig0ind[1] - 1;
setarray sigma,sigind,getArray(sigma,sigind)+
areshape(amult(amult(getArray(phi,phiind),
getArray(sigma,sig0ind)),
getArray(phi,phiind)),3|3);
loopnextindex philoop,phiind,gord;
loopnextindex sigloop,sigind,sigord;
The loopnextindex function in this example isn’t faster than the for loop used in the previous
section primarily because the code is looping only through the first dimension in each loop. The
advantages of loopnextindex, previousindex, nextindex, and walkindex are when the
code is looping through the higher dimensions of a highly dimensioned array. In this case, looping
through an array can be very complicated and difficult to manage using for loops.
loopnextindex can be faster and more useful.
The next example compares two ways of extracting a subarray from a 5-dimensional array:
ord = 3|3|3|3|3;
a = areshape(seqa(1,1,prodc(ord)),ord);
b = eye(3);
for i(1,3,1);
11-20
Working with Arrays
for j(1,3,1);
for k(1,3,1);
setarray a,i|j|k,b;
endfor;
endfor;
endfor;
ind = { 1,1,1 };
loopi:
setarray a,ind,b;
loopnextindex loopi,ind,ord;
Calling each loop 10,000 times and measuring the time each takes, we get
for loop: 1.171 seconds
loopnextindex: .321 seconds
In other words, loopnextindex is about four times faster, a very significant difference.
11.4.1
Working
with Arrays
11.4
Miscellaneous Array Functions
atranspose
This function changes the order of the dimensions. For example:
a = areshape(seqa(1,1,12),2|3|2);
print a;
Plane [1,.,.]
11-21
GAUSS User Guide
1.0000 2.0000
3.0000 4.0000
5.0000 6.0000
Plane [2,.,.]
7.0000 8.0000
9.0000 10.000
11.000 12.000
/*
** swap 2nd and 3rd dimension
*/
print atranspose(a,1|3|2);
Plane [1,.,.]
1.0000 3.0000 5.0000
2.0000 4.0000 6.0000
Plane [2,.,.]
7.0000 9.0000 11.000
8.0000 10.000 12.000
/*
** swap 1st and 3rd dimension
*/
print atranspose(a,3|2|1);
Plane [1,.,.]
1.0000 7.0000
3.0000 9.0000
5.0000 11.000
11-22
Working with Arrays
Plane [2,.,.]
2.0000 8.0000
4.0000 10.000
6.0000 12.000
/*
** move 3rd into the front
*/
print atranspose(a,3|1|2);
Plane [1,.,.]
1.0000 3.0000 5.0000
7.0000 9.0000 11.000
Plane [2,.,.]
2.0000 4.0000 6.0000
8.0000 10.000 12.000
amult
This function performs a matrix multiplication on the last two trailing dimensions of an array. The
leading dimensions must be strictly conformable, and the last two trailing dimensions must be
conformable in the matrix product sense. For example:
a = areshape(seqa(1,1,12),2|3|2);
b = areshape(seqa(1,1,16),2|2|4);
c = amult(a,b);
print a;
Plane [1,.,.]
11-23
Working
with Arrays
11.4.2
GAUSS User Guide
1.0000 2.0000
3.0000 4.0000
5.0000 6.0000
Plane [2,.,.]
7.0000 8.0000
9.0000 10.000
11.000 12.000
print b;
Plane [1,.,.]
1.0000 2.0000 3.0000 4.0000
5.0000 6.0000 7.0000 8.0000
Plane [2,.,.]
9.0000 10.000 11.000 12.000
13.000 14.000 15.000 16.000
print c;
Plane [1,.,.]
11.000 14.000 17.000 20.000
23.000 30.000 37.000 44.000
35.000 46.000 57.000 68.000
Plane [2,.,.]
167.00 182.00 197.00 212.00
211.00 230.00 249.00 268.00
255.00 278.00 301.00 324.00
11-24
Working with Arrays
Suppose we have a matrix of data sets, a 2×2 matrix of 100×5 data sets that we’ve stored in a
2×2×100×5 array called x. The moment matrices of these data sets can easily and quickly be
computed using atranspose and amult:
vc = amult(atranspose(x,1|2|4|3),x);
11.4.3
amean, amin, amax
These functions compute the means, minimums, and maximums, respectively, across a dimension
of an array. The size of the selected dimension of the resulting array is shrunk to one and contains
the means, minimums, or maximums depending on the function called. For example:
a = areshape(seqa(1,1,12),2|3|2);
print a;
Plane [1,.,.]
1.0000 2.0000
3.0000 4.0000
5.0000 6.0000
Working
with Arrays
Plane [2,.,.]
7.0000 8.0000
9.0000 10.000
11.000 12.000
/*
** compute means along third dimension
*/
print amean(a,3);
Plane [1,.,.]
11-25
GAUSS User Guide
4.0000 5.0000
6.0000 7.0000
8.0000 9.0000
/*
** print means along the second dimension, i.e.,
** down the columns
*/
print amean(a,2);
Plane [1,.,.]
3.0000 4.0000
Plane [2,.,.]
9.0000 10.000
/*
** print the minimums down the columns
*/
print amin(a,2);
Plane [1,.,.]
1.0000 2.0000
Plane [2,.,.]
7.0000 8.0000
/*
** print the maximums along the third dimension
*/
11-26
Working with Arrays
print amax(a,3);
Plane [1,.,.]
7.0000 8.0000
9.0000 10.000
11.000 12.000
11.4.4
getDims
This function returns the number of dimensions of an array:
a = arrayinit(4|4|5|2,0);
print getdims(a);
4.00
getOrders
This function returns the sizes of each dimension of an array. The length of the vector returned by
getOrders is the dimension of the array:
a = arrayinit(4|4|5|2,0);
print getOrders(a);
4.00
4.00
5.00
2.00
11-27
Working
with Arrays
11.4.5
GAUSS User Guide
11.4.6
arraytomat
This function converts an array with two or fewer dimensions to a matrix:
a = arrayinit(2|2,0);
b = arraytomat(a);
type(a);
21.000
type(b);
6.0000
11.4.7
mattoarray
This function converts a matrix to an array:
b = rndn(2,2);
a = mattoarray(b);
type(b);
6.0000
type(a);
21.000
11.5
Using Arrays with GAUSS functions
Many of the GAUSS functions have been re-designed to work with arrays. There are two general
approaches to this implementation. There are exceptions, however, and you are urged to refer to
the documention if you are not sure how a particular GAUSS function handles array input.
11-28
Working with Arrays
In the first approach, the function returns an element-by-element result that is strictly conformable
to the input. For example, cdfnc returns an array of identical size and shape to the input array:
a = areshape(seqa(-2,.5,12),2|3|2);
b = cdfnc(a);
print b;
Plane [1,.,.]
0.9772 0.9331
0.8413 0.6914
0.5000 0.3085
Plane [2,.,.]
0.1586 0.0668
0.0227 0.0062
0.0013 0.0002
Only the last two trailing dimensions matter; i.e., given a 2×3×4×5×10×6 array, moment returns a
2×3×4×5×6×6 array of moment matrices.
For example, in the following the result is a 2×3 array of 3×1 vectors of singular values of a 2×3
array of 6×3 matrices:
a = areshape(seqa(1,1,108),2|3|6|3);
b=svds(a);
print b;
11-29
Working
with Arrays
In the second approach, which applies generally to GAUSS matrix functions, the function operates
on the matrix defined by the last two trailing dimensions of the array. Thus, given a 5×10×3 array,
moment returns a 5×3×3 array of five moment matrices computed from the five 10×3 matrices in
the input array.
GAUSS User Guide
Plane [1,1,.,.]
45.894532
1.6407053
1.2063156e-015
Plane [1,2,.,.]
118.72909
0.63421188
5.8652600e-015
Plane [1,3,.,.]
194.29063
0.38756064
1.7162751e-014
Plane [2,1,.,.]
270.30524
0.27857175
1.9012118e-014
Plane [2,2,.,.]
346.47504
0.21732995
1.4501098e-014
Plane [2,3,.,.]
422.71618
0.17813229
1.6612287e-014
It might be tempting to conclude from this example that, in general, a GAUSS function’s behavior
11-30
Working with Arrays
on the last two trailing dimensions of an array is strictly analogous to the GAUSS function’s
behavior on a matrix. This may be true with some of the functions, but not all. For example, the
GAUSS meanc function returns a column result for matrix input. However, the behavior for the
GAUSS amean function is not analogous. This function takes a second argument that specifies on
which dimension the mean is to be taken. That dimension is then collapsed to a size of 1. Thus:
a = areshape(seqa(1,1,24),2|3|4);
print a;
Plane [1,.,.]
1.000 2.000 3.000 4.000
5.000 6.000 7.000 8.000
9.000 10.000 11.000 12.000
Plane [2,.,.]
13.000 14.000 15.000 16.000
17.000 18.000 19.000 20.000
21.000 22.000 23.000 24.000
/*
** means computed across rows
*/
Working
with Arrays
b = amean(a,1);
print b;
Plane [1,.,.]
2.500
6.500
10.500
Plane [2,.,.]
14.500
11-31
GAUSS User Guide
18.500
22.500
/*
** means computed down columns
*/
c = amean(a,2);
print c;
Plane [1,.,.]
5.000
6.000
7.000
8.000
Plane [2,.,.]
17.000 18.000 19.000 20.000
/*
** means computed along 3rd dimension
*/
d = amean(a,3);
print d;
Plane [1,.,.]
7.000 8.000 9.000 10.000
11.000 12.000 13.000 14.000
15.000 16.000 17.000 18.000
11.6
A Panel Data Model
Suppose we have N cases observed at T times. Let yit be an observation on a dependent variable
for the ith case at time t, Xit an observation of k independent variables for the ith case at time t, B, a
11-32
Working with Arrays
K×1 vector of coefficients. Then
yit = Xit B + µi + it
is a variance components model where µi is a random error term uncorrelated with it , but which is
correlated within cases. This implies an NT×NT residual moment matrix that is block diagonal
with N T×T moment matrices with the following form:
 2
σ2
...
σ2µ
 σµ + σ2

2
2
2
σµ
σµ + σ . . .
σ2µ


..
..
..
..

.
.
.
.

σ2µ
σ2µ
. . . σ2µ + σ2







The log-likelihood for this model is
lnL = −0.5(NT ln(2π) − ln | Ω | + (Y − XB)0Ω−1 (Y − XB))
where Ω is the block-diagonal moment matrix of the residuals.
Using GAUSS arrays, we can compute the log-likelihood of this model without resorting to do
loops. Let Y be a 100×3×1 array of observations on the dependent variable, and X a 100×3×5
array of observations on the independent variables. Further let B be a 5×1 vector of coefficients,
and sigu and sige be the residual variances of µ and respectively. Then, in explicit steps we
compute
N = 100;
T = 3;
K = 5;
11-33
Working
with Arrays
Computing the Log-likelihood
GAUSS User Guide
sigma = sigu * ones(T,T) + sige * eye(T); /* TxT sigma */
sigmai = invpd(sigma); /* sigma inverse */
lndet = N*ln(detl);
E = Y - amult(X,areshape(B,N|K|1)); /* residuals */
Omegai = areshape(sigmai,N|T|T); /* diagonal blocks */
/* stacked in a vector array */
R1 = amult(atranspose(E,1|3|2),Omegai); /* E’Omegai */
R2 = amult(R1,E); /* R1*E */
lnL = -0.5*(N*T*ln(2*pi) - lndet + asum(R2,3)); /* log-likelhood */
All of this can be made more efficient by nesting statements, which eliminates copying of
temporary intervening arrays to local arrays. It is also useful to add a check for the positive
definiteness of sigma:
N = 100;
T = 3;
K = 5;
const = -0.5*N*T*ln(2*pi);
oldt = trapchk(1);
trap 1,1;
sigmai = invpd(sigu*ones(T,T)+sige*eye(T));
trap oldt,1;
if not scalmiss(sigmai);
E = Y - amult(X,areshape(B,N|K|1));
lnl = const + 0.5*N*ln(detl)0.5*asum(amult(amult(atranspose(E,1|3|2),
areshape(sigmai,N|T|T)),E),3);
else;
lnl = error(0);
endif;
11-34
Working with Arrays
11.7
Appendix
This is an incomplete list of special functions for working with arrays. Many GAUSS functions
have been modified to handle arrays and are not listed here. For example, cdfnc computes the
complement of the Normal cdf for each element of an array just as it would for a matrix. See the
documentation for these GAUSS functions for information about their behavior with arrays.
Concatenate conformable matrices and arrays in a user-specified
dimension.
aeye
Create an array of identity matrices.
amax
Compute the maximum elements across a dimension of an array.
amean
Compute the mean along one dimension of an array.
amin
Compute the minimum elements across a dimension of an array.
amult
Perform a matrix multiplication on the last two trailing dimensions
of an array.
areshape
Reshape a scalar, matrix, or array into an array of user-specified size.
arrayalloc
Create an N-dimensional array with unspecified contents.
arrayinit
Create an N-dimensional array with a specified fill value.
arraytomat
Change an array to type matrix.
asum
Compute the sum across one dimension of an array.
atranspose
Transpose an N-dimensional array.
getarray
Get a contiguous subarray from an N-dimensional array.
getdims
Get the number of dimensions in an array.
getmatrix
Get a contiguous matrix from an N-dimensional array.
getmatrix4D
Get a contiguous matrix from a 4-dimensional array.
getorders
Get the vector of orders corresponding to an array.
Working
with Arrays
aconcat
11-35
GAUSS User Guide
11-36
getscalar3D
Get a scalar from a 3-dimensional array.
getscalar4D
Get a scalar form a 4-dimensional array.
loopnextindex
Increment an index vector to the next logical index and jump to the
specified label if the index did not wrap to the beginning.
mattoarray
Change a matrix to a type array.
nextindex
Return the index of the next element or subarray in an array.
previousindex
Return the index of the previous element or subarray in an array.
putarray
Put a contiguous subarray into an N-dimensional array and return
the resulting array.
setarray
Set a contiguous subarray of an N-dimensional array.
walkindex
Walk the index of an array forward or backward through a specified
dimension.
Structures
12.1
12.1.1
12
Basic Structures
Structure Definition
The syntax for a structure definition is
struct A { /* list of members */ };
The list of members can include scalars, arrays, matrices, strings, and string arrays, as well as
other structures. As a type, scalars are unique to structures and don’t otherwise exist.
Structures
For example, the following defines a structure containing the possible contents:
struct generic_example {
scalar x;
matrix y;
12-1
GAUSS User Guide
string s1;
string array s2
struct other_example t;
};
A useful convention is to put the structure definition into a file with a .sdf extension. Then, for
any command file or source code file that requires this definition, put
#include filename.sdf
For example:
#include example.sdf
These statements create structure definitions that persist until the workspace is cleared. They do
not create structures, only structure-type definitions. The next section describes how to create an
instance of a structure.
12.1.2
Declaring an Instance
To use a structure, it is necessary to declare an instance. The syntax for this is
struct structure type structure name;
For example:
#include example.sdf
struct generic_example p0;
12-2
Structures
12.1.3
Initializing an Instance
Members of structures are referenced using a “dot” syntax:
p0.x = rndn(20,3);
The same syntax applies when referred to on the right-hand side:
mn = meanc(p0.x);
Initialization of Global Structures
Global structures are initialized at compile time. Each member of the structure is initialized
according to the following schedule:
scalar
matrix
array
string
string array
0, a scalar zero
, an empty matrix with zero rows and zero columns
0, a 1-dimensional array set to zero
””, a null string
””, a 1×1 string array set to null
/* ds.src */
#include ds.sdf
proc dsCreate;
12-3
Structures
If a global already exists in memory, it will not be reinitialized. It may be the case in your program
that when it is rerun, the global variables may need to be reset to default values. That is, your
program may depend on certain members of a structure being set to default values that are set to
some other value later in the program. When you rerun this program, you will want to reinitialize
the global structure. To do this, make an assignment to at least one of the members. This can be
made convenient by writing a procedure that declares a structure and initializes one of its members
to a default value, and then returns it. For example:
GAUSS User Guide
struct DS d0;
d0.dataMatrix = 0;
retp(d0);
endp;
Calling this function after declaring an instance of the structure will ensure initialization to default
values each time your program is run:
struct DS d0;
d0 = dsCreate;
Initializing Local Structures
Local structures, which are structures defined inside procedures, are initialized at the first
assignment. The procedure may have been written in such a way that a subset of structures are
used an any one call, and in that case time is saved by not initializing the unused structures. They
will be initialized to default values only when the first assignment is made to one of its members.
12.1.4
Arrays of Structures
To create a matrix of instances, use the reshape command:
#include ds.sdf
struct DS p0;
p0 = reshape(dsCreate,5,1);
This creates a 5×1 vector of instances of DS structures, with all of the members initialized to
default values.
When the instance members have been set to some other values, reshape will produce multiple
copies of that instance set to those values.
Matrices or vectors of instances can also be created by concatenation:
12-4
Structures
#include trade.sdf
struct option p0,p1,p2;
p0 = optionCreate;
p1 = optionCreate;
p2 = p1 | p0;
12.1.5
Structure Indexing
Structure indexing may be used to reference a particular element in a structure array. The syntax
follows that of matrix indexing. For example, given the following structure definition:
struct example1 {
matrix x;
matrix y;
string str;
};
you could create an array of example1 structures and index it as follows:
struct example1 e1a;
struct example1 e1b;
e1a = e1a | e1b;
e1a[2,1].y = rndn(25,10);
Indexing of structure arrays can occur on multiple levels. For example, let’s define the following
structures:
struct example3 {
12-5
Structures
In this example, e1a and e1b are concatenated to create a 2×1 array of example1 structures that is
assigned back to e1a. Then the y member of the [2,1] element of e1a is set to a random matrix.
GAUSS User Guide
matrix w;
string array sa;
};
struct example2 {
matrix z;
struct example3 e3;
};
and let’s redefine example1 to include an instance of an example2 structure:
struct example1 {
matrix x;
matrix y;
string str;
struct example2 e2;
};
Let’s assume that we have an example1 structure e1 like the one displayed in Figure 12.1. We
could then index the structure as follows:
r = e1.e2[3,1].e3[2,1].w
You can also use indexing to reference the structure itself, rather than a member of that structure:
struct example3 e3tmp;
e3tmp = e1.e2[3,1].e3[2,1];
Or you can use indexing to reference a subarray of structures:
e3tmp = e1.e2[3,1].e3[.,1];
12-6
Structures
e1
matrix x
matrix y
string str
struct example2 e2
e2 is a 3x1 array
matrix z
struct example3 e3
matrix z
struct example3 e3
matrix z
struct example3 e3
e3 is a 2x1 array
e3 is a 1x1 array
e3 is a 3x1 array
matrix w
string aray sa
matrix w
string aray sa
matrix w
string aray sa
matrix w
string aray sa
matrix w
string aray sa
matrix w
string aray sa
Figure 12.1: Structure tree for e1
Structures
12-7
GAUSS User Guide
In this case, e3tmp would be an array of 3×1 example3 structures, since the [3,1] member of
e1.e2 contains a 3×1 array of example3 structures.
It is important to remember, however, that when indexing a structure array on multiple levels, only
the final index may resolve to an array of structures. For example:
e3tmp = e1.e2[.,1].e3[2,1];
would be invalid, since e1.e2[.,1] resolves to a 3×1 array of example2 structures.
12.1.6
Saving an Instance to the Disk
Instances and vectors or matrices of instances of structures can be saved in a file on the disk, and
later loaded from the file onto the disk. The syntax for saving an instance to the disk is
ret = savestruct(instance,filename);
The file on the disk will have an .fsr extension.
For example:
#include ds.sdf
struct DS p0;
p0 = reshape(dsCreate,2,1);
retc = saveStruct(p2,"p2");
This saves the vector of instances in a file called p2.fsr. retc will be zero if the save was
successful; otherwise, nonzero.
12-8
Structures
12.1.7
Loading an Instance from the Disk
The syntax for loading a file containing an instance or matrix of instances is
instance, retc
= loadstruct(file name,structure name);
For example:
#include trade.sdf;
struct DS p3;
{ p3, retc } = loadstruct("p2","ds");
12.1.8
Passing Structures to Procedures
Structures or members of structures can be passed to procedures. When a structure is passed as an
argument to a procedure, it is passed by value. The structure becomes a local copy of the structure
that was passed. The data in the structure is not duplicated unless the local copy of the structure
has a new value assigned to one of its members. Structure arguments must be declared in the
procedure definition:
struct rectangle {
matrix ulx;
matrix uly;
matrix lrx;
matrix lry;
};
Structures
proc area(struct rectangle rect);
retp((rect.lrx - rect.ulx).*(rect.uly - rect.lry));
endp;
Local structures are defined using a struct statement inside the procedure definition:
12-9
GAUSS User Guide
proc center(struct rectangle rect);
struct rectangle cent;
cent.lrx = (rect.lrx - rect.ulx) / 2;
cent.ulx = -cent.lrx;
cent.uly = (rect.uly - rect.lry) / 2;
cent.lry = -cent.uly;
retp(cent);
endp;
12.2
Structure Pointers
A structure pointer is a separate data type that contains the address of a structure and is used to
reference that structure.
12.2.1
Creating and Assigning Structure Pointers
Given the following structure type definition:
struct example_struct {
matrix x;
matrix y;
};
a pointer to an example_struct structure can be created with the following syntax:
struct example_struct *esp;
However, at this point, esp is not yet pointing at anything. It has only been defined to be the kind
of pointer that points at example_struct structures. To set it to point at a particular structure
instance, we must first create the structure instance:
12-10
Structures
struct example_struct es;
and then we can set esp to point at es by setting esp to the address of es:
esp = &es;
The following code:
struct example_struct es2;
es2 = *esp;
copies the contents of the structure that esp is pointing at (i.e., the contents of es) to es2. It is the
same as
struct example_struct es2;
es2 = es;
12.2.2
Structure Pointer References
To reference a member of a structure, we use a “dot” syntax. For example, we might use the
following code to set the x member of es.
es.x = rndn(3,3);
esp->x = rndn(10,5);
12-11
Structures
To reference a member of a structure using a pointer to that structure, we use an “arrow” syntax.
For example, we might use the following code to set the x member of es using the pointer esp:
GAUSS User Guide
This code will modify es, since esp is merely a pointer to es.
Structure pointers cannot be members of a structure. The following is illegal:
struct example_struct_2 {
matrix z;
struct example_struct *ep;
};
Therefore, since a structure pointer will never be a member of a structure, neither
sp1->sp2->x;
nor
s.sp1->x;
will ever be valid (sp1 and sp2 are assumed to be structure pointers, s a structure instance, and x a
matrix). The “arrow” (->) will only be valid if it is used for the first (or furthest left) dereference,
as in:
sp1->st.x;
At this point we do not support indexing of structure pointers. Thus, a structure pointer should
point at a scalar structure instance, not a matrix of structures. However, you may index members
of that scalar structure instance. So, for example, let us suppose that you defined the following
structure types:
struct sb {
matrix y;
matrix z;
12-12
Structures
};
struct sa {
matrix x;
struct structb s;
};
and then created an instance of an sa structure, a0, setting a0.s to a 3×2 matrix of sb structures.
The following would be legal:
struct sa *sap
sap = &a0;
sap->s[3,1].y = rndn(3,3);
12.2.3
Using Structure Pointers in Procedures
Structure pointers are especially useful in cases where structures are passed into and out of
procedures. If a procedure takes a structure as an argument and modifies any members of that
structure, then it makes a local copy of the entire structure before modifying it. Thus if you want
to have the modified copy of the structure after running the procedure, you need to pass the
structure out of the procedure as one of its return arguments. For example:
struct example_struct {
matrix x;
matrix y;
matrix z;
};
Structures
proc product(struct example_struct es);
es.z = (es.x).*(es.y);
retp(es);
endp;
struct example_struct es1;
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GAUSS User Guide
es1.x = rndn(1000,100);
es1.y = rndn(1000,1);
es1 = product(es1);
In this example, the structure es1 is passed into the procedure, copied and modified. The modified
structure is then passed out of the procedure and assigned back to es1.
Structure pointers allow you to avoid such excessive data copying and eliminate the need to pass a
structure back out of a procedure in cases like this. When you pass a structure pointer into a
procedure and then modify a member of the structure that it references, the actual structure is
modified rather than a local copy of it. Thus there is no need to pass the modifed structure back
out of the procedure. For example, the above example could be accomplished using structure
pointers as follows:
struct example_struct {
matrix x;
matrix y;
matrix z;
};
proc(0) = product(struct example_struct *esp);
esp->z = (esp->x).*(esp->y);
endp;
struct example_struct es1;
struct example_struct *es1p;
es1p = &es1;
es1.x = rndn(1000,100);
es1.y = rndn(1000,1);
product(es1p);
In this case, the procedure modifies the structure es1, which es1p is pointing at, instead of a local
copy of the structure.
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Structures
12.3
Special Structures
There are three common types of structures that will be found in the GAUSS Run-Time Library
and applications.
The DS and PV structures are defined in the GAUSS Run-Time Library. Their definitions are
found in ds.sdf and pv.sdf, respectively, in the src source code subdirectory.
Before structures, many procedures in the Run-Time Library and all applications had global
variables serving a variety of purposes, such as setting and altering defaults. Currently, these
variables are being entered as members of “control” structures.
12.3.1
The DS Structure
The DS structure, or “data” structure, is a very simple structure. It contains a member for each
GAUSS data type. The following is found in ds.sdf:
struct DS {
scalar type;
matrix dataMatrix;
array dataArray;
string dname;
string array vnames;
};
This structure was designed for use by the various optimization functions in GAUSS, in particular,
sqpSolvemt, as well as a set of gradient procedures, gradmt, hessmt, et al.
To initialize an instance of a DS structure, the procedure dsCreate is defined in ds.src:
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Structures
These procedures all require that the user provide a procedure computing a function (to be
optimized or take the derivative of, etc.), which takes the DS structure as an argument. The
Run-Time Library procedures such as sqpSolvemt take the DS structure as an argument and
pass it on to the user-provided procedure without modification. Thus, the user can put into that
structure whatever might be needed as data in the procedure.
GAUSS User Guide
#include ds.sdf
struct DS d0;
d0 = dsCreate;
12.3.2
The PV Structure
The PV structure, or parameter vector structure, is used by various optimization, modelling, and
gradient procedures, in particular sqpSolvemt, for handling the parameter vector. The GAUSS
Run-Time Library contains special functions that work with this structure. They are prefixed by
“pv” and defined in pv.src. These functions store matrices and arrays with parameters in the
structure, and retrieve various kinds of information about the parameters and parameter vector
from it.
“Packing” into a PV Structure
The various procedures in the Run-Time Library and applications for optimization, modelling,
derivatives, etc., all require a parameter vector. Parameters in complex models, however, often
come in matrices of various types, and it has been the responsibility of the programmer to generate
the parameter vector from the matrices and vice versa. The PV procedures make this problem
much more convenient to solve.
The typical situation involves two parts: first, “packing” the parameters into the PV structure,
which is then passed to the Run-Time Library procedure or application; and second,
“unpacking” the PV structure in the user-provided procedure for use in computing the objective
function. For example, to pack parameters into a PV structure:
#include sqpsolvemt.sdf
/* starting values */
b0 = 1; /* constant in mean equation */
garch = { .1, .1 }; /* garch parameters */
arch = { .1, .1 }; /* arch parameters */
omega = .1; /* constant in variance equation */
12-16
Structures
struct PV p0;
p0
p0
p0
p0
=
=
=
=
pvPack(pvCreate,b0,"b0");
pvPack(p0,garch,"garch");
pvPack(p0,arch,"arch");
pvPack(p0,omega,"omega");
/* data */
z = loadd("tseries");
struct DS d0;
d0.dataMatrix = z;
Next, in the user-provided procedure for computing the objective function, in this case minus the
log-likelihood, the parameter vector is unpacked:
proc ll(struct PV p0, struct DS d0);
local b0,garch,arch,omega,p,q,h,u,vc,w;
b0 = pvUnpack(p0,"b0");
garch = pvUnpack(p0,"garch");
arch = pvUnpack(p0,"arch");
omega = pvUnpack(p0,"omega");
p = rows(garch);
q = rows(arch);
Structures
u = d0.dataMatrix - b0;
vc = moment(u,0)/rows(u);
w = omega + (zeros(q,q) | shiftr((u.*ones(1,q))’,
seqa(q-1,-1,q))) * arch;
h = recserar(w,vc*ones(p,1),garch);
logl = -0.5 * ((u.*u)./h + ln(2*pi) + ln(h));
retp(logl);
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GAUSS User Guide
endp;
Masked Matrices
The pvUnpack function unpacks parameters into matrices or arrays for use in computations. The
first argument is a PV structure containing the parameter vector. Sometimes the matrix or vector is
partly parameters to be estimated (that is, a parameter to be entered in the parameter vector) and
partly fixed parameters. To distinguish between estimated and fixed parameters, an additional
argument is used in the packing function called a “mask”, which is strictly conformable to the
input matrix. Its elements are set to 1 for an estimated parameter and 0 for a fixed parameter. For
example:
p0 = pvPackm(p0,.1*eye(3),"theta",eye(3));
Here just the diagonal of a 3×3 matrix is added to the parameter vector.
When this matrix is unpacked, the entire matrix is returned with current values of the parameters
on the diagonal:
print pvUnpack(p0,"theta");
0.1000 0.0000 0.0000
0.0000 0.1000 0.0000
0.0000 0.0000 0.1000
Symmetric Matrices
Symmetric matrices are a special case because even if the entire matrix is to be estimated, only the
nonredundant portion is to be put into the parameter vector. Thus, for them there are special
procedures. For example:
12-18
Structures
vc = { 1 .6 .4, .6 1 .2, .4 .2 1 };
p0 = pvPacks(p0,vc,"vc");
There is also a procedure for masking in case only a subset of the nonredundant elements are to be
included in the parameter vector:
vc = { 1 .6 .4, .6 1 .2, .4 .2 1 };
mask = { 1 1 0, 1 1 0, 0 0 1 };
p0 = pvPacksm(p0,vc,"vc",mask);
Fast Unpacking
When unpacking matrices using a matrix name, pvUnpack has to make a search through a list of
names, which is relatively time-consuming. This can be alleviated by using an index rather than a
name in unpacking. To do this, though, requires using a special pack procedure that establishes the
index:
Structures
p0 = pvPacki(p0,b0,"b0",1);
p0 = pvPacki(p0,garch,"garch",2);
p0 = pvPacki(p0,arch,"arch",3);
p0 = pvPacki(p0,omega,"omega",4);
Now they may be unpacked using the index number:
b0 = pvUnpack(p0,1);
garch = pvUnpack(p0,2);
arch = pvUnpack(p0,3);
omega = pvUnpack(p0,4);
When packed with an index number, they may be unpacked either by index or by name, but
unpacking by index is faster.
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GAUSS User Guide
12.3.3
Miscellaneous PV Procedures
pvList
This procedure generates a list of the matrices or arrays packed into the structure:
p0 = pvPack(p0,b0,"b0");
p0 = pvPack(p0,garch,"garch");
p0 = pvPack(p0,arch,"arch");
p0 = pvPack(p0,omega,"omega");
print pvList(p0);
b0
garch
arch
omega
pvLength
This procedure returns the length of the parameter vector:
print pvLength(p0);
6.0000
pvGetParNames
This procedure generates a list of parameter names:
print pvGetParNames(p0);
12-20
Structures
b0[1,1]
garch[1,1]
garch[2,1]
arch[1,1]
arch[2,1]
omega[1,1]
pvGetParVector
This procedure returns the parameter vector itself:
print pvGetParVector(p0);
1.0000
0.1000
0.1000
0.1000
0.1000
1.0000
pvPutParVector
This procedure replaces the parameter vector with the one in the argument:
newp = { 1.5, .2, .2, .3, .3, .8 };
p0 = pvPutParVector(newp,p0);
print pvGetParVector(p0);
Structures
1.5000
0.2000
0.2000
0.3000
0.3000
0.8000
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GAUSS User Guide
pvGetIndex
This procedure returns the indices in the parameter vector of the parameters in a matrix. These
indices are useful when setting linear constraints or bounds in sqpSolvemt. Bounds, for example,
are set by specifying a K×2 matrix where K is the length of the parameter vector and the first
column are the lower bounds and the second the upper bounds. To set the bounds for a particular
parameter, then, requires knowing where that parameter is in the parameter vector. This
information can be found using pvGetIndex. For example:
// get indices of lambda parameters in parameter vector
lind = pvGetIndex(par0,"lambda");
// set bounds constraint matrix to unconstrained default
c0.bounds = ones(pvLength(par0),1).*(-1e250˜1e250);
// set bounds for lambda parameters to be positive
c0.bounds[lind,1] = zeros(rows(lind),1);
12.3.4
Control Structures
Another important class of structures is the “control” structure. Applications developed before
structures were introduced into GAUSS typically handled some program specifications by the use
of global variables which had some disadvantages, in particular, preventing the nesting of calls to
procedures.
Currently, the purposes served by global variables are now served by the use of a control structure.
For example, for sqpSolvemt:
struct sqpSolvemtControl {
matrix A;
matrix B;
matrix C;
matrix D;
scalar eqProc;
scalar ineqProc;
12-22
Structures
matrix
scalar
scalar
scalar
scalar
scalar
scalar
scalar
scalar
scalar
scalar
scalar
scalar
matrix
};
bounds;
gradProc;
hessProc;
maxIters;
dirTol;
CovType;
feasibleTest;
maxTries;
randRadius;
trustRadius;
seed;
output;
printIters;
weights;
The members of this structure determine optional behaviors of sqpSolvemt.
12.4
sqpSolvemt
sqpSolvemt is a procedure in the GAUSS Run-Time Library that solves the general nonlinear
programming problem using a Sequential Quadratic Programming descent method, that is, it
solves
min f (θ)
Aθ = B
Cθ>=D
H(θ) = 0
G(θ)>=0
θlb <=θ<=θub
Structures
subject to
linear equality
linear inequality
nonlinear equality
nonlinear inequality
bounds
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GAUSS User Guide
The linear and bounds constraints are redundant with respect to the nonlinear constraints, but are
treated separately for computational convenience.
The call to sqpSolvemt has four input arguments and one output argument:
out = SQPsolveMT(&fct,P,D,C);
12.4.1
Input Arguments
The first input argument is a pointer to the objective function to be minimized. The procedure
computing this objective function has two arguments: a PV structure containing the start values,
and a DS structure containing data, if any. For example:
proc fct(struct PV p0, struct DS d0);
local y, x, b0, b, e, s;
y = d0[1].dataMatrix;
x = d0[2].dataMatrix;
b0 = pvUnpack(p0,"constant");
b = pvUnpack(p0,"coefficients");
e = y - b0 - x * b;
s = sqrt(e’e/rows(e));
retp(-pdfn(e/s);
endp;
Note that this procedure returns a vector rather than a scalar. When the objective function is a
properly defined log-likelihood, returning a vector of minus log-probabilities permits the
calculation of a QML covariance matrix of the parameters.
The remaining input arguments are structures:
P
a PV structure containing starting values of the parameters
D
a DS structure containing data, if any
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Structures
an sqpSolvemtControl structure
C
The DS structure is optional. sqpSolvemt passes this argument on to the user-provided procedure
that &fct is pointing to without modification. If there is no data, a default structure can be passed
to it.
sqpSolvemtControl Structure
A default sqpSolvemtControl structure can be passed in the fourth argument for an
unconstrained problem. The members of this structure are as follows:
A
M×K matrix, linear equality constraint coecients: Aθ = B, where p is a
vector of the parameters.
B
M×1 vector, linear equality constraint constants: Aθ = B, where p is a
vector of the parameters.
C
M×K matrix, linear inequality constraint coefficients: Cθ = D, where p is a
vector of the parameters.
D
M×1 vector, linear inequality constraint constants: Cθ = D, where p is a
vector of the parameters.
eqProc
scalar, pointer to a procedure that computes the nonlinear equality
constraints. When such a procedure has been provided, it has two input
arguments, instances of PV and DS structures, and one output argument, a
vector of computed inequality constraints.
IneqProc
scalar, pointer to a procedure that computes the nonlinear inequality
constraints. When such a procedure has been provided, it has two input
arguments, instances of PV and DS structures, and one output argument, a
vector of computed inequality constraints.
Default = .; i.e., no inequality procedure.
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Structures
Default = .; i.e., no inequality procedure.
GAUSS User Guide
Bounds
1×2 or K×2 matrix, bounds on parameters. If 1×2 all parameters have same
bounds.
Default = -1e256 1e256 .
GradProc
scalar, pointer to a procedure that computes the gradient of the function
with respect to the parameters. When such a procedure has been provided,
it has two input arguments, instances of PV and DS structures, and one
output argument, the derivatives. If the function procedure returns a scalar,
the gradient procedure returns a 1×K row vector of derivatives. If function
procedure turns an N×1 vector, the gradient procedure returns an N×K
matrix of derivatives.
This procedure may compute a subset of the derivatives. sqpSolvemt will
compute numerical derivatives for all those elements set to missing values
in the return vector or matrix.
Default = .; i.e., no gradient procedure has been provided.
HessProc
scalar, pointer to a procedure that computes the Hessian; i.e., the matrix of
second order partial derivatives of the function with respect to the
parameters. When such a procedure has been provided, it has two input
arguments, instances of PV and DS structures, and one output argument, a
vector of computed inequality constraints.
Default = .; i.e., no Hessian procedure has been provided.
Whether the objective function procedure returns a scalar or vector, the
Hessian procedure must return a K×K matrix. Elements set to missing
values will be computed numerically by sqpSolvemt.
MaxIters
scalar, maximum number of iterations. Default = 1e+5.
MaxTries
scalar, maximum number of attemps in random search. Default = 100.
DirTol
scalar, convergence tolerance for gradient of estimated coefficients. Default
= 1e-5. When this criterion has been satisifed, sqpSolvemt exits the
iterations.
CovType
scalar, if 2, QML covariance matrix, else if 0, no covariance matrix is
computed, else ML covariance matrix is computed. For a QML covariance
matrix, the objective function procedure must return an N×1 vector of
minus log-probabilities.
12-26
Structures
FeasibleTest
scalar, if nonzero, parameters are tested for feasibility before computing
function in line search. If function is defined outside inequality boundaries,
then this test can be turned off. Default = 1.
randRadius
scalar, if zero, no random search is attempted. If nonzero, it is the radius of
the random search. Default = .001.
seed
scalar, if nonzero, seeds random number generator for random search,
otherwise time in seconds from midnight is used.
trustRadius
scalar, radius of the trust region. If scalar missing, trust region not applied.
The trust sets a maximum amount of the direction at each iteration. Default
= .001.
output
scalar, if nonzero, results are printed. Default = 0.
PrintIters
scalar, if nonzero, prints iteration information. Default = 0.
weights
vector, weights for objective function returning a vector. Default = 1.
12.4.2
Output Argument
The single output argument is an sqpSolvemtOut structure. Its definition is:
Structures
struct SQPsolveMTOut {
struct PV par;
scalar fct;
struct SQPsolveMTLagrange lagr;
scalar retcode;
matrix moment;
matrix hessian;
matrix xproduct;
};
The members of this structure are:
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GAUSS User Guide
par
instance of a PV structure containing the parameter estimates are placed in
the matrix member par.
fct
scalar, function evaluated at final parameter estimates.
lagr
an instance of an SQPLagrange structure containing the Lagrangeans for
the constraints. For an instance named lagr, the members are:
lagr.lineq
M×1 vector, Lagrangeans of linear equality
constraints
lagr.nlineq
N×1 vector, Lagrangeans of nonlinear equality
constraints
lagr.linineq
P×1 vector, Lagrangeans of linear inequality
constraints
lagr.nlinineq Q×1 vector, Lagrangeans of nonlinear inequality
constraints
lagr.bounds
K×2 matrix, Lagrangeans of bounds
Whenever a constraint is active, its associated Lagrangean will be nonzero.
For any constraint that is inactive throughout the iterations as well as at
convergence, the corresponding Lagrangean matrix will be set to a scalar
missing value.
retcode
12-28
return code:
0
normal convergence
1
forced exit
2
maximum number of iterations exceeded
3
function calculation failed
4
gradient calculation failed
5
Hessian calculation failed
6
line search failed
7
error with constraints
8
function complex
9
feasible direction couldn’t be found
Structures
12.4.3
Example
Define
Y = Λη + θ
where Λ is a K×L matrix of loadings, η an L×1 vector of unobserved “latent” variables, and θ a
K×1 vector of unobserved errors. Then
Σ = ΛΦΛ0Ψ
where Φ is the L×L covariance matrix of the latent variables, and Ψ is the K×K covariance matrix
of the errors.
The log-likelihood of the ith observation is
logP(i) = − 12 [Kln(2π) + ln | π | +Y(i)ΣY(i)0]
Not all elements of Λ, Φ, and Ψ can be estimated. At least one element of each column of Λ must
be fixed to 1, and Ψ is usually a diagonal matrix.
To ensure a well-defined log-likelihood, constraints on the parameters are required to guarantee
positive definite covariance matrices. To do this, a procedure is written that returns the eigenvalues
of Σ and Φ minus a small number. sqpSolvemt then finds parameters such that these eigenvalues
are greater than or equal to that small number.
12-29
Structures
Constraints
GAUSS User Guide
12.4.4
The Command File
This command file can be found in the file sqpfact.e in the examples subdirectory:
#include sqpsolvemt.sdf
lambda = { 1.0
0.5
0.0
0.0
lmask = { 0
1
0
0
0.0,
0.0,
1.0,
0.5 };
0,
0,
0,
1 };
phi = { 1.0 0.3,
0.3 1.0 };
psi = { 0.6
0.0
0.0
0.0
0.0
0.6
0.0
0.0
0.0
0.0
0.6
0.0
tmask = { 1
0
0
0
0
1
0
0
0,
0,
0,
1 };
struct
par0 =
par0 =
par0 =
par0 =
0
0
1
0
0.0,
0.0,
0.0,
0.6 };
PV par0;
pvCreate;
pvPackm(par0,lambda,"lambda",lmask);
pvPacks(par0,phi,"phi");
pvPacksm(par0,psi,"psi",tmask);
struct SQPsolveMTControl c0;
12-30
Structures
c0 = sqpSolveMTcontrolCreate;
lind = pvGetIndex(par0,"lambda"); /*
/*
/*
tind = pvGetIndex(par0,"psi");
/*
/*
/*
get indices of lambda */
parameters in parameter */
vector */
get indices of psi */
parameters in parameter */
vector */
c0.bounds = ones(pvLength(par0),1).*(-1e250˜1e250);
c0.bounds[lind,1] = zeros(rows(lind),1);
c0.bounds[lind,2] = 10*ones(rows(lind),1);
c0.bounds[tind,1] = .001*ones(rows(tind),1);
c0.bounds[tind,2] = 100*ones(rows(tind),1);
c0.output = 1;
c0.printIters = 1;
c0.trustRadius = 1;
c0.ineqProc = &ineq;
c0.covType = 1;
struct DS d0;
d0 = dsCreate;
d0.dataMatrix = loadd("maxfact");
output file = sqpfact.out reset;
struct SQPsolveMTOut out0;
out0 = SQPsolveMT(&lpr,par0,d0,c0);
Structures
lambdahat = pvUnpack(out0.par,"lambda");
phihat = pvUnpack(out0.par,"phi");
psihat = pvUnpack(out0.par,"psi");
print "estimates";
print;
print "lambda" lambdahat;
12-31
GAUSS User Guide
print;
print "phi" phihat;
print;
print "psi" psihat;
struct PV stderr;
stderr = out0.par;
if not scalmiss(out0.moment);
stderr = pvPutParVector(stderr,sqrt(diag(out0.moment)));
lambdase = pvUnpack(stderr,"lambda");
phise = pvUnpack(stderr,"phi");
psise = pvUnpack(stderr,"psi");
print "standard errors";
print;
print "lambda" lambdase;
print;
print "phi" phise;
print;
print "psi" psise;
endif;
output off;
proc lpr(struct PV par1, struct DS data1);
local lambda,phi,psi,sigma,logl;
lambda = pvUnpack(par1,"lambda");
phi = pvUnpack(par1,"phi");
psi = pvUnpack(par1,"psi");
sigma = lambda*phi*lambda’ + psi;
logl = -lnpdfmvn(data1.dataMatrix,sigma);
retp(logl);
endp;
proc ineq(struct PV par1, struct DS data1);
12-32
Structures
local lambda,phi,psi,sigma,e;
lambda = pvUnpack(par1,"lambda");
phi = pvUnpack(par1,"phi");
psi = pvUnpack(par1,"psi");
sigma = lambda*phi*lambda’ + psi;
e = eigh(sigma) - .001; /* eigenvalues of sigma */
e = e | eigh(phi) - .001; /* eigenvalues of phi */
retp(e);
endp;
Structures
12-33
RTL
Structures
Run-Time Library Structures
13
Two structures are used by several GAUSS Run-Time Library functions for handling parameter
vectors and data: the PV parameter structure and the DS data structure.
13.1
The PV Parameter Structure
The members of an instance of structure of type PV are all “private,” that is, not accessible directly
to the user. It is designed to handle parameter vectors for threadsafe optimization functions.
Entering and receiving parameter vectors, and accessing properties of this vector, are
accomplished using special functions.
Suppose you are optimizing a function containing a K×L matrix of coefficients. The optimization
function requires a parameter vector but your function uses a K×L matrix. Your needs and the
needs of the optimization function can be both satisfied by an instance of the structure of type PV.
For example:
struct PV p1;
p1 = pvCreate;
13-1
GAUSS User Guide
x = zeros(4,3); /* on input contains start values, */
/* on exit contains estimates
*/
p1 = pvPack(p1,x,"coefficients");
The pvCreate function initializes p1 to default values. pvPack enters the 4×3 matrix stored
row-wise as a 12×1 parameter vector for the optimization function. The optimization program will
pass the instance of the structure of type PV to your objective function.
By calling pvUnpack your 4×3 coefficient matrix is retrieved from the parameter vector. For
example, in your procedure you have
x = pvUnpack(p1,"coefficients");
and now x is a 4×3 matrix of coefficients for your use in calculating the object function.
Suppose that your objective function has parameters to be estimated in a covariance matrix. The
covariance matrix is a symmetric matrix where only the lower left portion contains unique values
for estimation. To handle this, use pvPacks. For example:
struct PV p1;
p1 = pvCreate;
cov = { 1 .1 .1,
.1 1 .1,
.1 .1 1 };
p1 = pvPacks(p1,cov,"covariance");
Only the lower left portion of cov will be stored in the parameter vector. When the covariance
matrix is unpacked, the parameters in the parameter vector will be entered into both the lower and
upper portions of the matrix.
There may be cases where only a portion of a matrix being used to compute the objective function
are parameters to be estimated. In this case use pvPackm with a “mask” matrix that contains ones
where parameters are to be estimated and zeros otherwise. For example,
13-2
struct PV p1;
p1 = pvCreate;
cov = { 1
.5
.5,
1 };
mask = { 0 1,
1 0 };
p1 = pvPacksm(p1,cov,"correlation",mask);
Here only the one element in the lower left of cov is stored in the parameter vector. Suppose the
optimization program sends a trial value for that parameter of, say, .45. When the matrix is
unpacked in your procedure it will contain the fixed values associated with the zeros in the mask
as well as the trial value in that part of the matrix associated with the ones. Thus,
print unpack(p1,"correlation");
1.0000
.4500
.4500
1.0000
A mask may also be used with general matrices to store a portion of a matrix in the parameter
vector.
struct PV p1;
p1 = pvCreate;
m =
{ 0 .5 1,
.5 0 .3 };
mask = { 0
1
1
0
1,
0};
p1 = pvPackm(p1,m,"coefficients",mask);
13-3
RTL
Structures
Run-Time Library Structures
GAUSS User Guide
A PV instance can, of course, hold parameters from all these types of matrices: symmetric, masked
symmetric, rectangular, and masked rectangular. For example:
lambda = { 1.0
0.5
0.0
0.0
lmask
= {
0
1
0
0
phi = { 1.0
0.3
struct
par0 =
par0 =
par0 =
par0 =
1
0
0
0
0,
0,
0,
1 };
0.3,
1.0 };
theta = { 0.6
0.0
0.0
0.0
tmask = {
0.0,
0.0,
1.0,
0.5 };
0.0
0.6
0.0
0.0
0.0
0.0
0.6
0.0
0.0,
0.0,
0.0,
0.6 };
0
1
0
0
0
0
1
0
0,
0,
0,
1 };
PV par0;
pvCreate;
pvPackm(par0,lambda,"lambda",lmask);
pvPacks(par0,phi,"phi");
pvPacksm(par0,theta,"theta",tmask);
It isn’t necessary to know where in the parameter vector the parameters are located in order to use
them in your procedure calculating the objective function. Thus:
lambda = pvUnpack(par1,"lambda");
13-4
phi = pvUnpack(par1,"phi");
theta = pvUnpack(par1,"theta");
sigma = lambda*phi*lambda’ + theta;
Additional functions are available to retrieve information on the properties of the parameter vector.
pvGetParVector and pvPutParVector get and put parameter vector from and into the PV
instance, pvGetParNames retrieves names for the elements of the parameter vector, pvList
returns the list of matrix names in the PV instance, pvLength the length of the parameter vector.
struct PV p1;
p1 = pvCreate;
cov = { 1
.5
.5,
1 };
mask = { 0 1,
1 0 };
p1 = pvPacksm(p1,cov,"correlation",mask);
print pvGetParVector(p1);
.5000
p1 = pvPutParVector(p1,.8);
print pvGetParVector(p1);
.8000
print pvUnpack(p1,"correlation");
1.0000
.8000
.8000
1.0000
print pvGetParNames(p1);
correlation[2,1]
13-5
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Run-Time Library Structures
GAUSS User Guide
print pvLength(p1);
1.0000
Also, pvTest tests an instance to make sure it is properly constructed. pvCreate generates an
initialized instance, and pvGetIndex returns the indices of the parameters of an input matrix in
the parameter vector. This last function is most useful when constructing linear constraint indices
for the optimization programs.
13.2
Fast Pack Functions
Unpacking matrices using matrix names is slow because it requires a string search through a string
array of names. A set of special packing functions are provided that avoid the search altogether.
These functions use a “table” of indices that you specify to find the matrix in the PV instance. For
example:
struct PV p1;
p1 = pvCreate;
y = rndn(4,1);
x = rndn(4,4);
p1 = pvPacki(p1,y,"Y",1);
p1 = pvPacki(p1,x,"X",2);
print pvUnpack(p1,1);
.3422
.0407
.5611
.0953
print pvUnpack(p1,"Y");
13-6
.3422
.0407
.5611
.0953
The call to pvPacki puts an entry in the table associating the matrix in its second argument with
the index 1. As indicated above the matrix can be unpacked either by index or by name.
Unpacking by index, however, is much faster than by name.
Note that the matrix can be unpacked using either the index or the matrix name.
There are index versions of all four of the packing functions, pvPacki, pvPackmi, pvPacksi, and
pvPacksmi.
13.3
The DS Data Structure
An instance of the DS data structure contains the following members:
struct DS d0;
d0.dataMatrix
d0.dataArray
d0.type
d0.dname
d0.vnames
M×K matrix, data
N-dimensional array, data
scalar
string
string array
The definition and use of the elements of d0 are determined by the particular application and are
mostly up to the user. A typical use might use a vector of structures. For example, suppose the
objective function requires a vector of observations on a dependent variable as well as on K
independent variables. Then:
13-7
RTL
Structures
Run-Time Library Structures
GAUSS User Guide
struct DS d0;
d0 = dsCreate;
y = rndn(20,1);
x = rndn(20,5);
d0 = reshape(d0,2,1);
d0[1].dataMatrix = y;
d0[2].dataMatrix = X;
The d0 instance would be passed to the optimization program which then passes it to your
procedure computing the objective function. For example:
proc lpr(struct PV p1, struct DS d1);
local u;
u = d0[1].dataMatrix - d0[2].dataMatrix * pvUnpack(p1,"beta");
retp(u’u);
endp;
A particular application may require setting other members of the DS instance for particular
purposes, but in general you may use them for your own purposes. For example, d0.dname could
be set to a GAUSS dataset name from which you read the data in the objective function procedure,
or d0.vnames could be set to the variable names of the columns of the data stored in
d0.dataMatrix, or d0.type could be an indicator variable for the elements of a vector of DS
instances.
The following are complete examples of the use of the PV and DS structures. The first example fits
a set of data to the Micherlitz model. It illustrates packing and unpacking by index.
#include sqpsolvemt.sdf
struct DS Y;
Y = dsCreate;
Y.dataMatrix = 3.183|
13-8
3.059|
2.871|
2.622|
2.541|
2.184|
2.110|
2.075|
2.018|
1.903|
1.770|
1.762|
1.550;
struct DS X;
X = dsCreate;
X.dataMatrix = seqa(1,1,13);
struct DS Z;
Z = reshape(Z,2,1);
Z[1] = Y;
Z[2] = X;
struct SQPsolveMTControl c1;
c1 = sqpSolveMTcontrolCreate; /* initializes
*/
/* default values */
c1.bounds = 0˜100;
/* constrains parameters */
/* to be positive
*/
c1.CovType = 1;
c1.output = 1;
c1.printIters = 0;
c1.gradProc = &grad;
struct PV par1;
par1 = pvCreate;
13-9
RTL
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Run-Time Library Structures
GAUSS User Guide
start = { 2, 4, 2 };
par1 = pvPacki(par1,start,"Parameters",1);
struct SQPsolveMTout out1;
out1 = SQPsolveMT(&Micherlitz,par1,Z,c1);
estimates = pvGetParVector(out1.par);
print " parameter estimates ";
print estimates;
print;
print " standard errors ";
print sqrt(diag(out1.moment));
proc Micherlitz(struct PV par1,struct DS Z);
local p0,e,s2;
p0 = pvUnpack(par1,1);
e = Z[1].dataMatrix - p0[1] - p0[2]*exp(-p0[3]
*Z[2].dataMatrix);
s2 = moment(e,0)/(rows(e)-1);
retp( (2/rows(e))*(e.*e/s2 + ln(2*pi*s2)));
endp;
proc grad(struct PV par1, struct DS Z);
local p0,e,e1,e2,e3,w,g,s2;
p0 = pvUnpack(par1,1);
w = exp(-p0[3]*Z[2].dataMatrix);
e = z[1].dataMatrix - p0[1] - p0[2] * w;
s2 = moment(e,0) / rows(e);
e1 = - ones(rows(e),1);
e2 = -w;
e3 = p0[2]*Z[2].dataMatrix.*w;
w = (1 - e.*e / s2) / rows(e);
g = e.*e1 + w*(e’e1);
g = g ˜ (e.*e2 + w*(e’e2));
g = g ˜ (e.*e3 + w*(e’e3));
13-10
retp(4*g/(rows(e)*s2));
endp;
This example estimates parameters of a “confirmatory factor analysis” model.
\#include sqpsolvemt.sdf
lambda = { 1.0
0.5
0.0
0.0
lmask
= {
0
1
0
0
phi = { 1.0
0.3
1
0
0
0
0,
0,
0,
1 };
0.3,
1.0 };
theta = { 0.6
0.0
0.0
0.0
tmask = {
0.0,
0.0,
1.0,
0.5 };
0.0
0.6
0.0
0.0
0.0
0.0
0.6
0.0
0.0,
0.0,
0.0,
0.6 };
0
1
0
0
0
0
1
0
0,
0,
0,
1 };
struct PV par0;
par0 = pvCreate;
par0 = pvPackm(par0,lambda,"lambda",lmask);
par0 = pvPacks(par0,phi,"phi");
par0 = pvPacksm(par0,theta,"theta",tmask);
13-11
RTL
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Run-Time Library Structures
GAUSS User Guide
struct SQPsolveMTControl c0;
c0 = sqpSolveMTcontrolCreate;
lind = pvGetIndex(par0,"lambda"); /* get indices of */
/* lambda parameters */
/* in parameter vector */
tind = pvGetIndex(par0,"theta"); /* get indices of */
/* theta parameters */
/* in parameter vector */
c0.bounds = ones(pvLength(par0),1).*(-1e250˜1e250);
c0.bounds[lind,1] = zeros(rows(lind),1);
c0.bounds[lind,2] = 10*ones(rows(lind),1);
c0.bounds[tind,1] = .001*ones(rows(tind),1);
c0.bounds[tind,2] = 100*ones(rows(tind),1);
c0.ineqProc = &ineq;
c0.covType = 1;
struct DS d0;
d0 = dsCreate;
d0.dataMatrix = loadd("maxfact");
struct SQPsolveMTOut out0;
out0 = SQPsolveMT(&lpr,par0,d0,c0);
lambdahat = pvUnpack(out0.par,"lambda");
phihat = pvUnpack(out0.par,"phi");
thetahat = pvUnpack(out0.par,"theta");
print "estimates";
print;
print "lambda" lambdahat;
print;
13-12
print "phi" phihat;
print;
print "theta" thetahat;
struct PV stderr;
stderr = out0.par;
if not scalmiss(out0.moment);
stderr =
pvPutParVector(stderr,sqrt(diag(out0.moment)));
lambdase = pvUnpack(stderr,"lambda");
phise = pvUnpack(stderr,"phi");
thetase = pvUnpack(stderr,"theta");
print "standard errors";
print;
print "lambda" lambdase;
print;
print "phi" phise;
print;
print "theta" thetase;
endif;
proc lpr(struct PV par1, struct DS data1);
local lambda,phi,theta,sigma,logl;
lambda = pvUnpack(par1,"lambda");
phi = pvUnpack(par1,"phi");
theta = pvUnpack(par1,"theta");
sigma = lambda*phi*lambda’ + theta;
logl = -lnpdfmvn(data1.dataMatrix,sigma);
retp(logl);
endp;
13-13
RTL
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Run-Time Library Structures
GAUSS User Guide
proc ineq(struct PV par1, struct DS data1);
local lambda,phi,theta,sigma,e;
lambda = pvUnpack(par1,"lambda");
phi = pvUnpack(par1,"phi");
theta = pvUnpack(par1,"theta");
sigma = lambda*phi*lambda’ + theta;
e = eigh(sigma) - .001; /* eigenvalues of sigma */
e = e | eigh(phi) - .001; /* eigenvalues of phi */
retp(e);
endp;
13-14
14
The term thread comes from the phrase “thread of execution”—simply, it denotes a section of code
that you want to execute. A single-threaded program has only one thread of execution, i.e., the
program itself. A multi-threaded program is one that can have multiple threads—sections of
code—executing simultaneously. Since these threads are part of the same program, they share the
same workspace, and see and operate on the same symbols. Threads allow you to take full
advantage of the hardware processing resources available on hyper-threaded, multi-core, and
multi-processor systems, executing independent calculations simultaneously, combining and using
the results of their work when done.
14.1
The Functions
GAUSS includes four keywords for multi-threading your programs:
ThreadStat
Marks a single statement to be executed as a thread.
ThreadBegin Marks the beginning of a block of code to be executed as a thread.
14-1
Threads
Multi-Threaded
Programming in GAUSS
GAUSS User Guide
ThreadEnd
Marks the end of a block of code to be executed as a thread.
ThreadJoin
Completes the definition of a set of threads, waits until they are done.
ThreadStat defines a single statement to be executed as a thread:
ThreadStat n = m’m;
ThreadBegin and ThreadEnd define a multi-line block of code to be executed as a thread:
ThreadBegin;
y = x’x;
z = y’y;
ThreadEnd;
Together these define sets of threads to be executed concurrently:
ThreadStat n = m’m;
ThreadBegin;
y = x’x;
z = y’y;
ThreadEnd;
ThreadBegin;
q = r’r;
r = q’q;
ThreadEnd;
ThreadStat p = o’o;
// Thread 1
// Thread 2
// Thread 3
// Thread 4
Finally, ThreadJoin completes the definition of a set of threads. It waits for the threads in a set to
finish and rejoin the creating (the parent) thread, which can then continue, making use of their
individual calculations:
14-2
Multi-Threaded Programming in GAUSS
14.2
// Thread 1
// Thread 2
//
//
//
//
Threads
ThreadBegin;
y = x’x;
z = y’y;
ThreadEnd;
ThreadBegin;
q = r’r;
r = q’q;
ThreadEnd;
ThreadStat n = m’m;
ThreadStat p = o’o;
ThreadJoin;
b = z + r + n’p;
Thread 3
Thread 4
waits for Threads 1-4 to finish
Using the results
GAUSS Threading Concepts
This is really the one and only thing you need to know about threads: threads are separate sections
of the same program, executing simultaneously, operating on the same data. In fact, it’s so
fundamental it’s worth saying again: threads are separate sections of code in a program, running at
the same time, using the same workspace, referencing and operating on the same symbols.
This raises basic issues of workflow and data integrity. How do you manage the creation and
execution of threads, and make use of the work they do? And how do you maintain data integrity?
(You do not want two threads assigning to the same symbol at the same time.)
To handle thread workflow, GAUSS employs a split-and-join approach. At various points in your
program (as many as you like), you define a set of threads that will be created and run as a group.
When created, the threads in the set execute simultaneously, each doing useful work. The parent
thread waits for the created threads to complete, then continues, the results of their work now
available for further use.
To maintain data integrity, we introduce the writer-must-isolate (informally, the
any-thread-can-read-unless-some-thread-writes) programming rule. That is to say, symbols that
are read from but not assigned to can be referenced by as many threads in a set as you like.
Symbols that are assigned to, however, must be wholly owned by a single thread. No other thread
in the set can reference that symbol. They cannot assign to it, nor can they read from it. They
cannot refer to it at all.
14-3
GAUSS User Guide
Note: the writer-must-isolate rule only applies to the threads within a given set (including any
child thread sets they may create). It does not apply between thread sets that have no chance of
running simultaneously.
For threads defined in the main code, the writer-must-isolate rule applies to the global symbols.
For threads defined in procedures or keywords, it applies to the global symbols, local symbols, and
the procedure/keyword arguments.
14.3
Coding With Threads
There are two main points to coding with threads.
One—you can define threads anywhere. You can define them in the main code, you can define
them in proc’s and keyword’s, and yes, you can define them inside other threads.
Two—you can call proc’s and keyword’s from threads. This is what really ties everything
together. You can call a proc from a thread, and that proc can create threads, and any of those
threads can call proc’s, and any of those proc’s can create threads, and ... you get the picture.
So—you can do things like this:
q = chol(b);
ThreadBegin;
x = q + m;
ThreadBegin;
y = x’x;
z = q’m;
ThreadEnd;
ThreadBegin;
a = b + x;
c = a + m;
ThreadEnd;
ThreadJoin;
q = m’c;
ThreadEnd;
14-4
Multi-Threaded Programming in GAUSS
Threads
ThreadBegin;
ThreadStat r = m’m;
ThreadStat s = m + inv(b);
ThreadJoin;
t = r’s;
ThreadEnd;
ThreadJoin;
x = r+s+q+z-t;
More importantly, you can do things like this:
proc bef(x);
local y,t;
ThreadStat y = nof(x);
ThreadStat t = dof(x’x);
ThreadJoin;
t = t+y;
retp(t);
endp;
proc abr(m);
local x,y,z,a,b;
a = m’m;
ThreadStat x = inv(m);
ThreadStat y = bef(m);
ThreadStat z = dne(a);
ThreadJoin;
b = chut(x,y,z,a);
retp(inv(b));
endp;
s = rndn(500,500);
14-5
GAUSS User Guide
ThreadStat t = abr(s);
ThreadStat q = abr(sˆ2);
ThreadStat r = che(s);
ThreadJoin;
w = del(t,q,r);
print w[1:10,1:10];
This means you can multi-thread anything you want, and call it from anywhere. You can
multi-thread all the proc’s and keyword’s in your libraries, and call them freely anywhere in your
multi-threaded programs.
14.4
Coding Restrictions
A few points on coding restrictions. First, you can’t interlace thread definition statements and
regular statements. You can’t do this:
ThreadStat a = b’b;
n = q;
ThreadStat c = d’d;
ThreadJoin;
Or this:
if k == 1;
ThreadStat a
elseif k == 2;
ThreadStat a
endif;
if j == 1;
ThreadStat d
elseif j == 2;
ThreadStat d
endif;
ThreadJoin;
14-6
= b’b;
= c’c;
= e’e;
= f’f;
Multi-Threaded Programming in GAUSS
Each set of threads is defined as a group, and always completed by a ThreadJoin, like this:
Threads
n = q;
ThreadStat a = b’b;
ThreadStat c = d’d;
ThreadJoin;
And this:
ThreadBegin;
if k == 1;
a = b’b;
elseif k == 2;
a = c’c;
endif;
ThreadEnd;
ThreadBegin;
if j == 1;
d = e’e;
elseif j == 2;
d = f’f;
endif;
ThreadEnd;
ThreadJoin;
Second—as stated above, you can reference read-only symbols in as many threads within a set as
you like, but any symbols that are assigned to must be wholly owned by a single thread. A symbol
that is assigned to by a thread cannot be written or read by any other thread in that set. This is the
writer-must-isolate rule.
So, you can do this:
ThreadStat x = y’y;
ThreadStat z = y+y;
14-7
GAUSS User Guide
ThreadStat a = b-y;
ThreadJoin;
You cannot do this:
ThreadStat x = y’y;
Threadstat z = x’x;
ThreadStat a = b-y;
ThreadJoin;
This is because the threads within a set run simultaneously. Thus, there is no way of knowing
when an assignment to a symbol has taken place, no way of knowing in one thread the “state” of a
symbol in another.
Let’s revisit the nested thread example for a minute and see how the writer-must-isolate rule
applies to it:
q = chol(b);
ThreadBegin;
x = q + m;
ThreadBegin;
y = x’x;
z = q’m;
ThreadEnd;
ThreadBegin;
a = b + x;
c = a + m;
ThreadEnd;
ThreadJoin;
q = m’c;
ThreadEnd;
ThreadBegin;
ThreadStat r = m’m;
ThreadStat
s = m + inv(b);
14-8
// main code, no threads yet
// Th1: isolates x,y,z,a,c,q from Th2
// Th1.1: isolates y,z from 1.2
// Th1.2: isolates a,c from 1.1
// Joins 1.1, 1.2
// Th2: isolates r,s,t from Th1
// Th2.1: isolates r from 2.2
// Th2.2: isolates s from 2.1
Multi-Threaded Programming in GAUSS
// Joins 2.1, 2.1
// Joins Th1, Th2
The main point here is that any symbols a thread or its children assign to must be isolated from all
the other threads (and their children) of the same nesting level in that set. On the other hand, the
children of a thread can freely read/write symbols that are read/written by their parent, because
there is no risk of simultaneity; they must only isolate written symbols from their siblings and
siblings’ offspring.
If you break the writer-must-isolate rule, your program (and probably GAUSS) will crash.
Worse, until it crashes, it will be happily producing indeterminate results.
Finally—the ThreadEnd command is what tells a thread to terminate, so you mustn’t write code
that keeps a thread from reaching it. For example, don’t retp from the middle of a thread:
ThreadStat m = imt( 9 );
ThreadBegin;
x = q[1];
if x = 1;
retp(z);
else;
r = z + 2;
endif;
ThreadEnd;
ThreadJoin;
And don’t use goto to jump into or out of the middle of a thread:
retry:
ThreadBegin;
{ err, x } = fna(q);
if err;
14-9
Threads
ThreadJoin;
t = r’s;
ThreadEnd;
ThreadJoin;
x = r+s+q+z-t;
GAUSS User Guide
goto badidea;
endif;
x = fnb(x);
ThreadEnd;
ThreadStat y = fnb(y);
ThreadJoin;
z = fnc(x,y);
save z;
end;
badidea:
errorlog "Error computing fna(q)";
q = fnd(q);
goto retry;
Basically, don’t do anything that will keep a thread from reaching its ThreadEnd command.
That’s the only way it knows its work is done. end and stop are okay to call, though—they will
bring the program to an end as usual, and terminate all running threads in the process.
(You can use goto and labels to jump around within a thread—that is, within the confines of a
ThreadBegin/ThreadEnd pair.)
14-10
Libraries
The GAUSS library system allows for the creation and maintenance of modular programs. The
user can create “libraries” of frequently used functions that the GAUSS system will automatically
find and compile whenever they are referenced in a program.
15.1
Autoloader
The autoloader resolves references to procedures, keywords, matrices, and strings that are not
defined in the program from which they are referenced. The autoloader automatically locates and
compiles the files containing the symbol definitions that are not resolved during the compilation of
the main file. The search path used by the autoloader is first the current directory, and then the
paths listed in the src_path configuration variable in the order they appear. src_path can be
defined in the GAUSS configuration file.
15-1
Libraries
15
GAUSS User Guide
15.1.1
Forward References
When the compiler encounters a symbol that has not previously been defined, that is called a
“forward reference”. GAUSS handles forward references in two ways, depending on whether they
are “left-hand side” or “right-hand side” references.
Left-Hand Side
A left-hand side reference is usually a reference to a symbol on the left-hand side of the equal sign
in an expression.
x = 5;
Left-hand side references, since they are assignments, are assumed to be matrices. In the statement
above, x is assumed to be a matrix and the code is compiled accordingly. If, at execution time, the
expression actually returns a string, the assignment is made and the type of the symbol x is forced
to string.
Some commands are implicit left-hand side assignments. There is an implicit left-hand side
reference to x in each statement below:
clear x;
load x;
open x = myfile;
Right-Hand Side
A right-hand side reference is usually a reference to a symbol on the right-hand side of the equal
sign in an expression such as:
15-2
Libraries
z = 6;
y = z + dog;
print y;
In the program above, since dog is not previously known to the compiler, the autoloader will
search for it in the active libraries. If it is found, the file containing it will be compiled. If it is not
found in a library, the autoload/autodelete state will determine how it is handled.
15.1.2
The Autoloader Search Path
If the autoloader is ON, GAUSS searches for unresolved symbol references during compilation
using a specific search path as outlined below. If the autoloader is OFF, an Undefined symbol
error message will result for right-hand side references to unknown symbols.
When autoload is ON, the autodelete state controls the handling of references to unknown
symbols.
The following search path will be followed to locate any symbols not previously defined:
Autodelete ON
1. user library
2. user-specified libraries.
3. gauss library
4. current directory, then src_path for files with a .g extension.
Forward references are allowed and .g files need not be in a library. If there are symbols that
cannot be found in any of the places listed above, an Undefined symbol error message will be
15-3
Libraries
If the autoloader is OFF, no forward references are allowed. Every procedure, matrix, and string
referenced by your program must be defined before it is referenced. An external statement can
be used above the first reference to a symbol, but the definition of the symbol must be in the main
file or in one of the files that are #include’d. No global symbols are deleted automatically.
GAUSS User Guide
generated and all uninitialized variables and all procedures with global references will be deleted
from the global symbol table. This autodeletion process is transparent to the user, since the
symbols are automatically located by the autoloader the next time the program is run. This process
results in more compile time, which may or may not be significant, depending on the speed of the
computer and the size of the program.
Autodelete OFF
1. user library
2. user-specified libraries.
3. gauss library
All .g files must be listed in a library. Forward references to symbols that are not listed in an
active library are not allowed. For example:
x = rndn(10,10);
y = sym(x);
/* Forward reference to sym */
proc sym(x);
retp(x+x’);
endp;
Use an external statement for anything referenced above its definition if autodelete is OFF:
external proc sym;
x = rndn(10,10);
y = sym(x);
proc sym(x);
retp(x+x’);
endp;
15-4
Libraries
When autodelete is OFF, symbols not found in an active library will not be added to the symbol
table. This prevents the creation of uninitialized procedures in the global symbol table. No
deletion of symbols from the global symbol table will take place.
Libraries
Suppose you have several procedures that are all related and you want them all defined in the same
file. You can create such a file, and, with the help of a library, the autoloader will be able to find
the procedures defined in that file whenever they are called.
First, create the file that is to contain your desired procedure definitions. By convention, this file is
usually named with a .src extension, but you may use any name and any file extension. In this
file, put all the definitions of related procedures you wish to use. Here is an example of such a file.
It is called norm.src:
/*
**
**
**
**
**
**
*/
norm.src
This is a file containing the definitions of three
procedures which return the norm of a matrix x.
The three norms calculated are the 1-norm, the
inf-norm and the E-norm.
proc onenorm(x);
retp(maxc(sumc(abs(x))));
endp;
proc infnorm(x);
15-5
Libraries
The first place GAUSS looks for a symbol definition is in the “active” libraries. A GAUSS library
is a text file that serves as a dictionary to the source files that contain the symbol definitions. When
a library is active, GAUSS will look in it whenever it is looking for a symbol it is trying to resolve.
The library statement is used to make a library active. Library files should be located in the
subdirectory listed in the lib_path configuration variable. Library files have an .lcg extension.
GAUSS User Guide
retp(maxc(sumc(abs(x’))));
endp;
proc Enorm(x);
retp(sumc(sumc(x.*x)));
endp;
Next, create a library file that contains the name of the file you want access to, and the list of
symbols defined in it. This can be done with the lib command. (For details, see lib in the
GAUSS L R.)
A library file entry has a filename that is flush left. The drive and path can be included to speed up
the autoloader. Indented below the filename are the symbols included in the file. There can be
multiple symbols listed on a line, with spaces between. The symbol type follows the symbol
name, with a colon delimiting it from the symbol name. The valid symbol types are:
fn
user-defined single line function.
keyword
keyword.
proc
procedure.
matrix
matrix, numeric or character.
array
N-dimensional array.
string
string.
sparse matrix
sparse matrix.
struct
structure.
A structure is always denoted by struct followed by the structure type name.
If the symbol type is missing, the colon must not be present and the symbol type is assumed to be
proc. Both library files below are valid:
Example 1
15-6
Libraries
/*
** math
**
** This library lists files and procedures for mathematical routines.
*/
Libraries
norm.src
onenorm:proc infnorm:proc Enorm:proc
complex.src
cmmult:proc cmdiv:proc cmadd:proc cmsoln:proc
poly.src
polychar:proc polyroot:proc polymult:proc
Example 2
/*
** math
**
** This library lists files and procedures for mathematical routines.
*/
c:\gauss\src\norm.src
onenorm : proc
infnorm : proc
Enorm : proc
c:\gauss\src\complex.src
cmmult : proc
cmdiv : proc
cmadd : proc
cmsoln : proc
c:\gauss\src\fcomp.src
feq : proc
fne : proc
flt : proc
fgt : proc
fle : proc
15-7
GAUSS User Guide
fge : proc
c:\gauss\src\fcomp.dec
_fcmptol : matrix
Once the autoloader finds, via the library, the file containing your procedure definition, everything
in that file will be compiled. For this reason, you should combine related procedures in the same
file in order to minimize the compiling of procedures not needed by your program. In other words,
you should not combine unrelated functions in one .src file because if one function in a .src file
is needed, the whole file will be compiled.
user Library
This is a library for user-created procedures. If the autoloader is ON, the user library is the first
place GAUSS looks when trying to resolve symbol references.
You can update the user library with the lib command as follows:
lib user myfile.src
This will update the user library by adding a reference to myfile.src.
No user library is shipped with GAUSS. It will be created the first time you use the lib
command to update it.
For details on the parameters available with the lib command, see the GAUSS L
R.
.g Files
If autoload and autodelete are ON and a symbol is not found in a library, the autoloader will
assume it is a procedure and look for a file that has the same name as the symbol and a .g
extension. For example, if you have defined a procedure called square, you could put the
definition in a file called square.g in one of the subdirectories listed in your src_path. If
autodelete is OFF, the .g file must be listed in an active library; for example, in the user library.
15-8
Libraries
15.2
Global Declaration Files
If your application makes use of several global variables, create a file containing declare
statements. Use files with the extension .dec to assign default values to global matrices and
strings with declare statements and to declare global N-dimensional arrays, sparse matrices,
and structures, which will be initialized as follows:
Initializes To
1-dimensional array of 1 containing 0
empty sparse matrix
1×1 structure containing empty and/or zeroed out members
In order to declare structures in a .dec file, you must #include the file(s) containing the
definitions of the types of structures that you wish to declare at the top of your .dec file. For
example, if you have the following structure type definition in a file called mystruct.sdf:
struct mystruct {
matrix m;
array a;
scalar scal;
string array sa;
};
You could declare an instance of that structure type, called ms, in a .dec file as follows:
#include mystruct.sdf
declare struct mystruct ms;
See declare in the C R, Chapter 29, for more information.
A file with a .ext extension containing the same symbols in external statements can also be
created and #include’d at the top of any file that references these global variables. An
15-9
Libraries
Variable Type
N-dimensional array
sparse matrix
structure
GAUSS User Guide
appropriate library file should contain the name of the .dec files and the names of the globals they
declare. This allows you to reference global variables across source files in an application.
Here is an example that illustrates the way in which .dec, .ext, .lcg and .src files work
together. Always begin the names of global matrices or strings with ‘_’ to distinguish them from
procedures.
.src File:
/*
** fcomp.src
**
** These functions use _fcmptol to fuzz the comparison operations
** to allow for roundoff error.
**
** The statement:
y = feq(a,b);
**
** is equivalent to:
y = a eq b;
**
** Returns a scalar result, 1 (true) or 0 (false)
**
**
y = feq(a,b);
**
y = fne(a,b);
*/
#include fcomp.ext
proc feq(a,b);
retp(abs(a-b) <= _fcmptol);
endp;
proc fne(a,b);
retp(abs(a-b) > _fcmptol);
endp;
.dec File:
15-10
Libraries
/*
** fcomp.dec - global declaration file for fuzzy comparisons.
*/
declare matrix _fcmptol != 1e-14;
.ext File:
external matrix _fcmptol;
.lcg File:
/*
** fcomp.lcg - fuzzy compare library
*/
fcomp.dec
_fcmptol:matrix
fcomp.src
feq:proc
fne:proc
With the exception of the library (.lcg) files, these files must be located along your src_path.
The library files must be on your lib_path. With these files in place, the autoloader will be able
to find everything needed to run the following programs:
library fcomp;
x = rndn(3,3);
xi = inv(x);
15-11
Libraries
/*
** fcomp.ext - external declaration file for fuzzy comparisons.
*/
GAUSS User Guide
xix = xi*x;
if feq(xix,eye(3));
print "Inverse within tolerance.";
else;
print "Inverse not within tolerance.";
endif;
If the default tolerance of 1e-14 is too tight, the tolerance can be relaxed:
library fcomp;
x = rndn(3,3);
xi = inv(x);
xix = xi*x;
_fcmptol = 1e-12;
/* reset tolerance */
if feq(xix,eye(3));
print "Inverse within tolerance.";
else;
print "Inverse not within tolerance.";
endif;
15.3
Troubleshooting
Below is a partial list of errors you may encounter in using the library system, followed by the
most probable cause.
(4) :
error G0290 :
’/gauss/lib/prt.lcg’ :
Library not found
The autoloader is looking for a library file called prt.lcg, because it has been activated
in a library statement. Check the subdirectory listed in your lib_path configuration
variable for a file called prt.lcg.
(0) :
15-12
error G0292 :
’prt.dec’ :
File listed in library not found
Libraries
The autoloader cannot find a file called prt.dec. Check for this file. It should exist
somewhere along your src_path, if you have it listed in prt.lcg.
Undefined symbols:
PRTVEC /gauss/src/tstprt.g(2)
The symbol prtvec could not be found. Check if the file containing prtvec is in the
src_path. You may have not activated the library that contains your symbol definition.
Do so in a library statement.
You are trying to illegally force a symbol to another type. You probably have a name
conflict that needs to be resolved by renaming one of the symbols.
/gauss/lib/prt.lcg(5) :
library
error G0301 :
’prt.dec’ :
Syntax error in
Undefined symbols:
__VNAMES /gauss/src/prt.src(6)
Check your library to see that all filenames are flush left and that all the symbols defined
in that file are indented by at least one space.
15.3.1
Using .dec Files
Below is some advice you are encouraged to follow when constructing your own library system:
• Whenever possible, declare variables in a file that contains only declare statements. When
your program is run again without clearing the workspace, the file containing the variable
declarations will not be compiled and declare warnings will be prevented.
• Provide a function containing regular assignment statements to reinitialize the global
variables in your program if they ever need to be reinitialized during or between runs. Put
this in a separate file from the declarations:
15-13
Libraries
/gauss/src/prt.dec(3) : Redefinition of ’__vnames’ (proc)__vnames being
declared external matrix
GAUSS User Guide
proc (0) =
_vname
_con =
_row =
_title
endp;
globset;
= "X";
1;
0;
= "";
• Never declare any global in more than one file.
• To avoid meaningless redefinition errors and declare warnings, never declare a global
more than once in any one file. Redefinition error messages and declare warnings are
meant to help you prevent name conflicts, and will be useless to you if your code generates
them normally.
By following these guidelines, any declare warnings and redefinition errors you get will be
meaningful. By knowing that such warnings and errors are significant, you will be able to debug
your programs more efficiently.
15-14
Compiler
16
Compiler
GAUSS allows you to compile your large, frequently used programs to a file that can be run over
and over with no compile time. The compiled image is usually smaller than the uncompiled
source. GAUSS is not a native code compiler; rather, it compiles to a form of pseudocode. The file
will have a .gcg extension.
The compile command will compile an entire program to a compiled file. An attempt to edit a
compiled file will cause the source code to be loaded into the editor if it is available to the system.
The run command assumes a compiled file if no extension is given, and that a file with a .gcg
extension is in the src_path. A saveall command is available to save the current contents of
memory in a compiled file for instant recall later. The use command will instantly load a
compiled program or set of procedures at the beginning of an ASCII program before compiling the
rest of the ASCII program file.
Since the compiled files are encoded binary files, the compiler is useful for developers who do not
want to distribute their source code.
16-1
GAUSS User Guide
16.1
Compiling Programs
Programs are compiled with the compile command.
16.1.1
Compiling a File
Source code program files that can be run with the run command can be compiled to .gcg files
with the compile command:
compile qxy.e;
All procedures, global matrices, arrays, strings and string arrays, and the main program segment
will be saved in the compiled file. The compiled file can be run later using the run command. Any
libraries used in the program must be present and active during the compile, but not when the
program is run. If the program uses the dlibrary command, the .dll files must be present when
the program is run and the dlibrary path must be set to the correct subdirectory. This will be
handled automatically in your configuration file. If the program is run on a different computer than
it was compiled on, the .dll files must be present in the correct location. sysstate (case 24) can
be used to set the dlibrary path at run-time.
16.2
Saving the Current Workspace
The simplest way to create a compiled file containing a set of frequently used procedures is to use
saveall and an external statement:
library pgraph;
external proc xy,logx,logy,loglog,hist;
saveall pgraph;
Just list the procedures you will be using in an external statement and follow it with a saveall
statement. It is not necessary to list procedures that you do not explicitly call, but are called from
16-2
Compiler
another procedure, because the autoloader will automatically find them before the saveall
command is executed. Nor is it necessary to list every procedure you will be calling, unless the
source will not be available when the compiled file is use’d.
Remember, the list of active libraries is NOT saved in the compiled file, so you may still need a
library statement in a program that is use’ing a compiled file.
16.3
Debugging
If you are using compiled code in a development situation in which debugging is important,
compile the file with line number records. After the development is over, you can recompile
without line number records if the maximum possible execution speed is important. If you want to
guarantee that all procedures contain line number records, put a new statement at the top of your
program and turn line number tracking on.
Compiler
16-3
File I/O
17
The following is a partial list of the I/O commands in the GAUSS programming language:
Close a file.
closeall
Close all open files.
colsf
Number of columns in a file.
create
Create GAUSS data set.
eof
Test for end of file.
fcheckerr
Check error status of a file.
fclearerr
Check error status of a file and clear error flag.
fflush
Flush a file’s output buffer.
fgets
Read a line of text from a file.
fgetsa
Read multiple lines of text from a file.
File I/O
close
17-1
GAUSS User Guide
fgetsat
Read multiple lines of text from a file, discarding newlines.
fgetst
Read a line of text from a file, discarding newline.
fileinfo
Return names and information of files matching a specification.
files
Return a directory listing as a character matrix.
filesa
Return a list of files matching a specification.
fopen
Open a file.
fputs
Write strings to a file.
fputst
Write strings to a file, appending newlines.
fseek
Reposition file pointer.
fstrerror
Get explanation of last file I/O error.
ftell
Get position of file pointer.
getf
Load a file into a string.
getname
Get variable names from data set.
iscplxf
Return whether a data set is real or complex.
load
Load matrix file or small ASCII file (same as loadm).
loadd
Load a small GAUSS data set into a matrix.
loadm
Load matrix file or small ASCII file.
loads
Load string file.
open
Open a GAUSS data set.
output
Control printing to an auxiliary output file or device.
readr
Read a specified number of rows from a file.
rowsf
Number of rows in file.
save
Save matrices, strings, procedures.
17-2
File I/O
saved
Save a matrix in a GAUSS data set.
seekr
Reset read/write pointer in a data set.
sortd
Sort a data set.
typef
Return type of data set (bytes per element).
writer
Write data to a data set.
17.1
ASCII Files
GAUSS has facilities for reading and writing ASCII files. Since most software can also read and
write ASCII files, this provides one method of sharing data between GAUSS and many other
kinds of programs.
17.1.1
Matrix Data
Reading
For small delimited data files, the load statement can be used to load the data directly into a
GAUSS matrix. The resulting GAUSS matrix must be no larger than the limit for a single matrix.
For example,
load x[] = dat1.asc;
will load the data in the file dat1.asc into an N×1 matrix x. This method is preferred because
rows(x) can be used to determine how many elements were actually loaded, and the matrix can
be reshape’d to the desired form:
17-3
File I/O
Files containing numeric data that are delimited with spaces or commas and are small enough to fit
into a single matrix or string can be read with load. Larger ASCII data files can be converted to
GAUSS data sets with the ATOG utility program (see ATOG, Chapter 24). ATOG can convert
packed ASCII files as well as delimited files.
GAUSS User Guide
load x[] = dat1.asc;
if rows(x) eq 500;
x = reshape(x,100,5);
else;
errorlog "Read Error";
end;
endif;
For quick interactive loading without error checking, use
load x[100,5] = dat1.asc;
This will load the data into a 100×5 matrix. If there are more or fewer than 500 numbers in the
data set, the matrix will automatically be reshaped to 100×5.
Writing
To write data to an ASCII file the print or printfm command is used to print to the auxiliary
output. The resulting files are standard ASCII files and can be edited with GAUSS’s editor or
another text editor.
The output and outwidth commands are used to control the auxiliary output. The print or
printfm command is used to control what is sent to the output file.
The window can be turned on and off using screen. When printing a large amount of data to the
auxiliary output, the window can be turned off using the command
screen off;
This will make the process much faster, especially if the auxiliary output is a disk file.
It is easy to forget to turn the window on again. Use the end statement to terminate your
programs; end will automatically perform screen on and output off.
The following commands can be used to control printing to the auxiliary output:
17-4
File I/O
format
Specify format for printing a matrix.
output
Open, close, rename auxiliary output file or device.
outwidth
Set auxiliary output width.
printfm
Formatted matrix print.
print
Print matrix or string.
screen
Turn printing to the window on and off.
This example illustrates printing a matrix to a file:
format /rd 8,2;
outwidth 132;
output file = myfile.asc reset;
screen off;
print x;
output off;
screen on;
A more extended example follows. This program will write the contents of the GAUSS file
mydata.dat into an ASCII file called mydata.asc. If there is an existing file by the name of
mydata.asc, it will be overwritten:
output file = mydata.asc reset;
screen off;
format /rd 1,8;
open fp = mydata;
do until eof(fp);
print readr(fp,200);;
17-5
File I/O
The numbers in the matrix x will be printed with a field width of 8 spaces per number, and with 2
places beyond the decimal point. The resulting file will be an ASCII data file. It will have 132
column lines maximum.
GAUSS User Guide
endo;
fp = close(fp);
end;
The output ... reset command will create an auxiliary output file called mydata.asc to
receive the output. The window is turned off to speed up the process. The GAUSS data file
mydata.dat is opened for reading and 200 rows are read per iteration until the end of the file is
reached. The data read are printed to the auxiliary output mydata.asc only, because the window
is off.
17.1.2
General File I/O
getf will read a file and return it in a string variable. Any kind of file can be read in this way as
long as it will fit into a single string variable.
To read files sequentially, use fopen to open the file and use fgets, fputs, and associated
functions to read and write the file. The current position in a file can be determined with ftell.
The following example uses these functions to copy an ASCII text file:
proc copy(src, dest);
local fin, fout, str;
fin = fopen(src, "rb");
if not fin;
retp(1);
endif;
fout = fopen(dest, "wb");
if not fin;
call close(fin);
retp(2);
endif;
do until eof(fin);
17-6
File I/O
str = fgets(fin, 1024);
if fputs(fout, str) /= 1;
call close(fin);
call close(fout);
retp(3);
endif;
endo;
call close(fin);
call close(fout);
retp(0);
endp;
17.2
Data Sets
GAUSS data sets are the preferred method of storing data contained in a single matrix for use
within GAUSS. Use of these data sets allows extremely fast reading and writing of data. Many
library functions are designed to read data from these data sets.
If you want to store multiple variables of various types in a single file, see GAUSS D A,
Section 17.3.
File I/O
17.2.1
Layout
GAUSS data sets are arranged as matrices; that is, they are organized in terms of rows and
columns. The columns in a data file are assigned names, and these names are stored in the header,
or, in the case of the v89 format, in a separate header file.
The limit on the number of rows in a GAUSS data set is determined by disk size. The limit on the
number of columns is limited by RAM. Data can be stored in 2, 4, or 8 bytes per number, rather
than just 8 bytes as in the case of GAUSS matrix files.
The ranges of the different formats are:
17-7
GAUSS User Guide
Bytes
Type
Significant Digits
2
4
8
integer
single
double
4
6-7
15-16
17.2.2
Range
-32768 <= X <= 32767
8.43E-37 <= |X| <= 3.37E+38
4.19E-307 <= |X| <= 1.67E+308
Creating Data Sets
Data sets can be created with the create or datacreate command. The names of the columns,
the type of data, etc., can be specified. (For details, see create in the GAUSS L
R.)
Data sets, unlike matrices, cannot change from real to complex, or vice-versa. Data sets are always
stored a row at a time. The rows of a complex data set, then, have the real and imaginary parts
interleaved, element by element. For this reason, you cannot write rows from a complex matrix to
a real data set—there is no way to interleave the data without rewriting the entire data set. If you
must, explicitly convert the rows of data first, using the real and imag functions (see the GAUSS
L R), and then write them to the data set. Rows from a real matrix CAN be
written to a complex data set; GAUSS simply supplies 0’s for the imaginary part.
To create a complex data set, include the complex flag in your create command.
17.2.3
Reading and Writing
The basic functions in GAUSS for reading data files are open and readr:
open f1 = dat1;
x = readr(f1,100);
The call to readr in this example will read in 100 rows from dat1.dat. The data will be assigned
to a matrix x.
loadd and saved can be used for loading and saving small data sets.
17-8
File I/O
The following example illustrates the creation of a GAUSS data file by merging (horizontally
concatenating) two existing data sets:
file1 = "dat1";
file2 = "dat2";
outfile = "daty";
open fin1 = ˆfile1 for read;
open fin2 = ˆfile2 for read;
varnames = getname(file1)|getname(file2);
otyp = maxc(typef(fin1)|typef(fin2));
create fout = ˆoutfile with ˆvarnames,0,otyp;
nr = 400;
do until eof(fin1) or eof(fin2);
y1 = readr(fin1,nr);
y2 = readr(fin2,nr);
r = maxc(rows(y1)|rows(y2));
y = y1[1:r,.] ˜ y2[1:r,.];
call writer(fout,y);
endo;
closeall fin1,fin2,fout;
17.2.4
Distinguishing Character and Numeric Data
Although GAUSS itself does not distinguish between numeric and character columns in a matrix
or data set, some of the GAUSS Application programs do. When creating a data set, it is important
to indicate the type of data in the various columns. The following discusses two ways of doing this.
17-9
File I/O
In this example, data sets dat1.dat and dat2.dat are opened for reading. The variable names
from each data set are read using getname, and combined in a single vector called varnames. A
variable called otyp is created, which will be equal to the larger of the two data types of the input
files. This will insure that the output is not rounded to less precision than the input files. A new
data set daty.dat is created using the create ... with ... command. Then, on every
iteration of the loop, 400 rows are read in from each of the two input data sets, horizontally
concatenated, and written out to daty.dat. When the end of one of the input files is reached,
reading and writing will stop. The closeall command is used to close all files.
GAUSS User Guide
Using Type Vectors
The v89 data set format distinguished between character and numeric data in data sets by the case
of the variable names associated with the columns. The v96 data set format, however, stores this
type information separately, resulting in a much cleaner and more robust method of tracking
variable types, and greater freedom in the naming of data set variables.
When you create a data set, you can supply a vector indicating the type of data in each column of
the data set. For example:
data = { M 32 21500,
F 27 36000,
F 28 19500,
M 25 32000 };
vnames = { "Sex" "Age" "Pay" };
vtypes = { 0 1 1 };
create f = mydata with ˆvnames, 3, 8, vtypes;
call writer(f,data);
f = close(f);
To retrieve the type vector, use vartypef.
open f = mydata for read;
vn = getnamef(f);
vt = vartypef(f);
print vn’;
print vt’;
Sex
0
Age
1
Pay
1
The call to getnamef in this example returns a string array rather than a character vector, so you
can print it without the ‘$’ prefix.
17-10
File I/O
Using the Uppercase/Lowercase Convention (v89 Data Sets)
Historically, some GAUSS Application programs recognized an “uppercase/lowercase”
convention: if the variable name was uppercase, the variable was assumed to be numeric, and if it
was lowercase, the variable was assumed to be character.
However, this is now obsolete; use vartypef and v96 data sets to be compatible with future
versions.
17.3
GAUSS Data Archives
The GAUSS Data Archive (GDA) is extremely powerful and flexible, giving you much greater
control over how you store your data. There is no limitation on the number of variables that can be
stored in a GDA, and the only size limitation is the amount of available disk space. Moreover,
GDA’s are designed to hold whatever type of data you want to store in them. You may write
matrices, arrays, strings, string arrays, sparse matrices, and structures to a GDA, and the GDA will
keep track of the type, size and location of each of the variables contained in it. Since GAUSS
now supports reading and writing to GDA’s that were created on other platforms, GDA’s provide a
simple solution to the problem of sharing data across platforms.
See Section 17.5.12 for information on the layout of a GDA.
File I/O
17.3.1
Creating and Writing Variables to GDA’s
To create a GAUSS Data Archive, call gdaCreate, which creates a GDA containing only header
information. It is recommended that file names passed into gdaCreate have a .gda extension;
however, gdaCreate will not force an extension.
To write variables to the GDA, you must call gdaWrite. A single call to gdaWrite writes only
one variable to the GDA. Writing multiple variables requires multiple calls to gdaWrite.
For example, the following code:
ret = gdaCreate("myfile.gda",1);
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GAUSS User Guide
ret = gdaWrite("myfile.gda",rndn(100,50),"x1");
ret = gdaWrite("myfile.gda","This is a string","str1");
ret = gdaWrite("myfile.gda",394,"x2");
produces a GDA containing the following variables:
Index
Name
Type
Size
1
2
3
x1
str1
x2
matrix
string
matrix
100 × 50
16 chars
1×1
17.3.2
Reading Variables from GDA’s
The following table details the commands that you may use to read various types of variables from
a GAUSS Data Archive:
Variable Type
matrix
array
string
string array
sparse matrix
structure
Read Command(s)
gdaRead
gdaReadByIndex
gdaReadSparse
gdaReadStruct
gdaRead, gdaReadSparse, and gdaReadStruct take a variable name and return the variable
data. gdaReadByIndex returns the variable data for a specified variable index.
For example, to get the variable x1 out of myfile.gda, you could call:
y = gdaRead("myfile.gda","x1");
or
y = gdaReadByIndex("myfile.gda",1);
17-12
File I/O
If you want to read only a part of a matrix, array, string, or string array from a GDA, call
gdaReadSome. Sparse matrices and structures may not be read in parts.
17.3.3
Updating Variables in GDA’s
To overwrite an entire variable in a GDA, you may call gdaUpdate or gdaUpdateAndPack. If the
new variable is not the same size as the variable that it is replacing, gdaUpdate will leave empty
bytes in the file, while gdaUpdateAndPack will pack the file (from the location of the variable
that is being replaced to the end of the file) to remove those empty bytes.
gdaUpdate is usually faster, since it does not move data in the file unnecessarily. However, calling
gdaUpdate several times for one file may result in a file with a large number of empty bytes.
On the other hand, gdaUpdateAndPack uses disk space efficiently, but it may be slow for large
files (especially if the variable to be updated is one of the first variables in the file).
If speed and disk space are both concerns and you are going to update several variables, it will be
most efficient to use gdaUpdate to update the variables and then call gdaPack once at the end to
pack the file.
The syntax is the same for both gdaUpdate and gdaUpdateAndPack:
File I/O
ret = gdaUpdate("myfile.gda",rndn(1000,100),"x1");
ret = gdaUpdateAndPack("myfile.gda",rndn(1000,100),"x1");
To overwrite part of a variable in a GDA, call gdaWriteSome.
17.4
Matrix Files
GAUSS matrix files are files created by the save command.
17-13
GAUSS User Guide
The save command takes a matrix in memory, adds a header that contains information on the
number of rows and columns in the matrix, and stores it on disk. Numbers are stored in double
precision just as they are in matrices in memory. These files have the extension .fmt.
Matrix files can be no larger than a single matrix. No variable names are associated with matrix
files.
GAUSS matrix files can be load’ed into memory using the load or loadm command or they can
be opened with the open command and read with the readr command. With the readr
command, a subset of the rows can be read. With the load command, the entire matrix is load’ed.
GAUSS matrix files can be open’ed for read, but not for append, or for update.
If a matrix file has been opened and assigned a file handle, rowsf and colsf can be used to
determine how many rows and columns it has without actually reading it into memory. seekr and
readr can be used to jump to particular rows and to read them into memory. This is useful when
only a subset of rows is needed at any time. This procedure will save memory and be much faster
than load’ing the entire matrix into memory.
17.5
File Formats
This section discusses the GAUSS binary file formats.
There are four currently supported matrix file formats:
Version
Extension
Support
Small Matrix v89
Extended Matrix v89
Matrix v92
Universal Matrix v96
.fmt
.fmt
.fmt
.fmt
Obsolete, use v96.
Obsolete, use v96.
Obsolete, use v96.
Supported for read/write.
There are four currently supported string file formats:
17-14
File I/O
Version
Extension
Support
Small String v89
Extended String v89
String v92
Universal String v96
.fst
.fst
.fst
.fst
Obsolete, use v96.
Obsolete, use v96.
Obsolete, use v96.
Supported for read/write.
There are four currently supported data set formats:
Version
Extension
Support
Small Data Set v89
.dat,
.dht
.dat,
.dht
.dat
.dat
Obsolete, use v96.
Extended Data Set v89
Data Set v92
Universal Data Set v96
17.5.1
Obsolete, use v96.
Obsolete, use v96.
Supported for read/write.
Small Matrix v89 (Obsolete)
Matrix files are binary files, and cannot be read with a text editor. They are created with save.
Matrix files with up to 8190 elements have a .fmt extension and a 16-byte header formatted as
follows:
Description
0-1
2-3
4-5
6-7
8-9
10-15
DDDD hex, identification flag
rows, unsigned 2-byte integer
columns, unsigned 2-byte integer
size of file minus 16-byte header, unsigned 2-byte integer
type of file, 0086 hex for real matrices, 8086 hex for complex matrices
reserved, all 0’s
File I/O
Offset
The body of the file starts at offset 16 and consists of IEEE format double precision floating point
numbers or character elements of up to 8 characters. Character elements take up 8 bytes and are
padded on the right with zeros. The size of the body of the file is 8*rows*cols rounded up to the
next 16-byte paragraph boundary. Numbers are stored row by row. A 2×3 real matrix will be
17-15
GAUSS User Guide
stored on disk in the following way, from the lowest addressed element to the highest addressed
element:
[1, 1] [1, 2] [1, 3] [2, 1] [2, 2] [2, 3]
For complex matrices, the size of the body of the file is 16*rows*cols. The entire real part of the
matrix is stored first, then the entire imaginary part. A 2×3 complex matrix will be stored on disk
in the following way, from the lowest addressed element to the highest addressed element:
(real part)
[1, 1] [1, 2] [1, 3] [2, 1] [2, 2] [2, 3]
(imaginary part) [1, 1] [1, 2] [1, 3] [2, 1] [2, 2] [2, 3]
17.5.2
Extended Matrix v89 (Obsolete)
Matrices with more than 8190 elements are saved in an extended format. These files have a
16-byte header formatted as follows:
Offset
Description
0-1
2-3
4-7
8-11
12-15
EEDD hex, identification flag
type of file, 0086 hex for real matrices, 8086 hex for complex matrices
rows, unsigned 4-byte integer
columns, unsigned 4-byte integer
size of file minus 16-byte header, unsigned 4-byte integer
The size of the body of an extended matrix file is 8*rows*cols (not rounded up to a paragraph
boundary). Aside from this, the body is the same as the small matrix v89 file.
17.5.3
Small String v89 (Obsolete)
String files are created with save. String files with up to 65519 characters have a 16-byte header
formatted as follows:
17-16
File I/O
Offset
Description
0-1
2-3
4-5
6-7
8-9
10-15
DFDF hex, identification flag
1, unsigned 2-byte integer
length of string plus null byte, unsigned 2-byte integer
size of file minus 16-byte header, unsigned 2-byte integer
001D hex, type of file
reserved, all 0’s
The body of the file starts at offset 16. It consists of the string terminated with a null byte. The size
of the file is the 16-byte header plus the length of the string and null byte rounded up to the next
16-byte paragraph boundary.
17.5.4
Extended String v89 (Obsolete)
Strings with more than 65519 characters are saved in an extended format. These files have a
16-byte header formatted as follows:
Description
0-1
2-3
4-7
8-11
12-15
EEDF hex, identification flag
001D hex, type of file
1, unsigned 4-byte integer
length of string plus null byte, unsigned 4-byte integer
size of file minus 16-byte header, unsigned 4-byte integer
File I/O
Offset
The body of the file starts at offset 16. It consists of the string terminated with a null byte. The size
of the file is the 16-byte header plus the length of the string and null byte rounded up to the next
8-byte boundary.
17.5.5
Small Data Set v89 (Obsolete)
All data sets are created with create. v89 data sets consist of two files; one .dht contains the
header information; the second (.dat) contains the binary data. The data will be one of three types:
17-17
GAUSS User Guide
8-byte IEEE floating point
4-byte IEEE floating point
2-byte signed binary integer, twos complement
Numbers are stored row by row.
The .dht file is used in conjunction with the .dat file as a descriptor file and as a place to store
names for the columns in the .dat file. Data sets with up to 8175 columns have a .dht file
formatted as follows:
Offset
Description
0-1
2-5
6-7
8-9
10-11
12-13
14-17
18-21
22-23
24-127
DADA hex, identification flag
reserved, all 0’s
columns, unsigned 2-byte integer
row size in bytes, unsigned 2-byte integer
header size in bytes, unsigned 2-byte integer
data type in .dat file (2 4 8), unsigned 2-byte integer
reserved, all 0’s
reserved, all 0’s
control flags, unsigned 2-byte integer
reserved, all 0’s
Column names begin at offset 128 and are stored 8 bytes each in ASCII format. Names with less
than 8 characters are padded on the right with bytes of 0.
The number of rows in the .dat file is calculated in GAUSS using the file size, columns, and data
type. This means that users can modify the .dat file by adding or deleting rows with other
software without updating the header information.
Names for the columns should be lowercase for character data, to be able to distinguish them from
numeric data with vartype.
GAUSS currently examines only the 4’s bit of the control flags. This bit is set to 0 for real data
sets, 1 for complex data sets. All other bits are 0.
Data sets are always stored a row at a time. A real data set with 2 rows and 3 columns will be
stored on disk in the following way, from the lowest addressed element to the highest addressed
17-18
File I/O
element:
[1, 1] [1, 2] [1, 3]
[2, 1] [2, 2] [2, 3]
The rows of a complex data set are stored with the real and imaginary parts interleaved, element
by element. A 2×3 complex data set, then, will be stored on disk in the following way, from the
lowest addressed element to the highest addressed element:
[1, 1]r [1, 1]i [1, 2]r [1, 2]i [1, 3]r [1, 3]i
[2, 1]r [2, 1]i [2, 2]r [2, 2]i [2, 3]r [2, 3]i
17.5.6
Extended Data Set v89 (Obsolete)
Data sets with more than 8175 columns are saved in an extended format that cannot be read by the
16-bit version. These files have a .dht descriptor file formatted as follows:
Description
0-1
2-3
4-7
8-11
12-15
16-19
20-23
24-27
28-29
30-127
EEDA hex, identification flag
data type in .dat file (2 4 8), unsigned 2-byte integer
reserved, all 0’s
columns, unsigned 4-byte integer
row size in bytes, unsigned 4-byte integer
header size in bytes, unsigned 4-byte integer
reserved, all 0’s
reserved, all 0’s
control flags, unsigned 2-byte integer
reserved, all 0’s
File I/O
Offset
Aside from the differences in the descriptor file and the number of columns allowed in the data
file, extended data sets conform to the v89 data set description specified above.
17-19
GAUSS User Guide
17.5.7
Matrix v92 (Obsolete)
Offset
Description
0-3
4-7
8-11
12-15
16-19
20-23
24-27
always 0
always 0xEECDCDCD
reserved
reserved
reserved
0 - real matrix, 1 - complex matrix
number of dimensions
0 - scalar
1 - row vector
2 - column vector, matrix
header size, 128 + number of dimensions * 4, padded to 8-byte boundary
reserved
28-31
32-127
If the data is a scalar, the data will directly follow the header.
If the data is a row vector, an unsigned integer equaling the number of columns in the vector will
precede the data, along with 4 padding bytes.
If the data is a column vector or a matrix, there will be two unsigned integers preceding the data.
The first will represent the number of rows in the matrix and the second will represent the number
of columns.
The data area always begins on an even 8-byte boundary. Numbers are stored in double precision
(8 bytes per element, 16 if complex). For complex matrices, all of the real parts are stored first,
followed by all the imaginary parts.
17.5.8
String v92 (Obsolete)
Offset
Description
0-3
4-7
always 0
always 0xEECFCFCF
17-20
File I/O
Offset
Description
8-11
12-15
16-19
20-23
24-27
28-127
reserved
reserved
reserved
size of string in units of 8 bytes
length of string plus null terminator in bytes
reserved
The size of the data area is always divisible by 8, and is padded with nulls if the length of the string
is not evenly divisible by 8. If the length of the string is evenly divisible by 8, the data area will be
the length of the string plus 8. The data area follows immediately after the 128-byte header.
17.5.9
Data Set v92 (Obsolete)
Description
0-3
4-7
8-11
12-15
16-19
20-23
24-27
28-31
32-35
36-39
40-127
always 0
always 0xEECACACA
reserved
reserved
reserved
rows in data set
columns in data set
0 - real data set, 1 - complex data set
type of data in data set, 2, 4, or 8
header size in bytes is 128 + columns * 9
reserved
File I/O
Offset
The variable names begin at offset 128 and are stored 8 bytes each in ASCII format. Each name
corresponds to one column of data. Names less than 8 characters are padded on the right with
bytes of zero.
The variable type flags immediately follow the variable names. They are 1-byte binary integers,
one per column, padded to an even 8-byte boundary. A 1 indicates a numeric variable and a 0
indicates a character variable.
17-21
GAUSS User Guide
The contents of the data set follow the header and start on an 8-byte boundary. Data is either 2-byte
signed integer, 4-byte single precision floating point or 8-byte double precision floating point.
17.5.10
Matrix v96
Offset
Description
0-3
4-7
8-11
12-15
16-19
20-23
24-27
28-31
32-35
36-39
40-43
44-47
48-51
52-55
56-59
always 0xFFFFFFFF
always 0
always 0xFFFFFFFF
always 0
always 0xFFFFFFFF
0xFFFFFFFF for forward byte order, 0 for backward byte order
0xFFFFFFFF for forward bit order, 0 for backward bit order
always 0xABCDEF01
currently 1
reserved
floating point type, 1 for IEEE 754
1008 (double precision data)
8, the size in bytes of a double matrix
0 - real matrix, 1 - complex matrix
1 - imaginary part of matrix follows real part (standard GAUSS style)
2 - imaginary part of each element immediately follows real part
(FORTRAN style)
number of dimensions
0 - scalar
1 - row vector
2 - column vector or matrix
1 - row major ordering of elements, 2 - column major
always 0
header size, 128 + dimensions * 4, padded to 8-byte boundary
reserved
60-63
64-67
68-71
72-75
76-127
If the data is a scalar, the data will directly follow the header.
If the data is a row vector, an unsigned integer equaling the number of columns in the vector will
17-22
File I/O
precede the data, along with 4 padding bytes.
If the data is a column vector or a matrix, there will be two unsigned integers preceding the data.
The first will represent the number of rows in the matrix and the second will represent the number
of columns.
The data area always begins on an even 8-byte boundary. Numbers are stored in double precision
(8 bytes per element, 16 if complex). For complex matrices, all of the real parts are stored first,
followed by all the imaginary parts.
17.5.11
Data Set v96
Description
0-3
4-7
8-11
12-15
16-19
20-23
24-27
28-31
32-35
36-39
40-43
44-47
always 0xFFFFFFFF
always 0
always 0xFFFFFFFF
always 0
always 0xFFFFFFFF
0xFFFFFFFF for forward byte order, 0 for backward byte order
0xFFFFFFFF for forward bit order, 0 for backward bit order
0xABCDEF02
version, currently 1
reserved
floating point type, 1 for IEEE 754
12 - signed 2-byte integer
1004 - single precision floating point
1008 - double precision float
2, 4, or 8, the size of an element in bytes
0 - real matrix, 1 - complex matrix
1 - imaginary part of matrix follows real part (standard GAUSS style)
2 - imaginary part of each element immediately follows real part
(FORTRAN style)
always 2
1 for row major ordering of elements, 2 for column major
48-51
52-55
56-59
60-63
64-67
File I/O
Offset
17-23
GAUSS User Guide
Offset
Description
68-71
72-75
76-79
80-83
84-87
88-127
always 0
header size, 128 + columns * 33, padded to 8-byte boundary
reserved
rows in data set
columns in data set
reserved
The variable names begin at offset 128 and are stored 32 bytes each in ASCII format. Each name
corresponds to one column of data. Names less than 32 characters are padded on the right with
bytes of zero.
The variable type flags immediately follow the variable names. They are 1-byte binary integers,
one per column, padded to an even 8-byte boundary. A 1 indicates a numeric variable and a 0
indicates a character variable.
Contents of the data set follow the header and start on an 8-byte boundary. Data is either 2-byte
signed integer, 4-byte single precision floating point or 8-byte double precision floating point.
17.5.12
GAUSS Data Archive
A GAUSS Data Archive consists of a header, followed by the variable data and, finally, an array of
variable descriptors containing information about each variable.
Header
The header for a GAUSS Data Archive is laid out as follows:
Offset
Type
Description
0-3
4-7
8-11
32-bit unsigned integer
32-bit unsigned integer
32-bit unsigned integer
always 0xFFFFFFFF
always 0
always 0xFFFFFFFF
17-24
File I/O
Offset
Type
Description
12-15
16-19
20-23
32-bit unsigned integer
32-bit unsigned integer
32-bit unsigned integer
24-27
28-31
32-35
36-39
40-43
44-55
56-63
64-67
68-95
96-103
32-bit unsigned integer
32-bit unsigned integer
32-bit unsigned integer
32-bit unsigned integer
32-bit unsigned integer
32-bit unsigned integers
64-bit unsigned integer
32-bit unsigned integer
32-bit unsigned integers
64-bit unsigned integer
104-127
64-bit unsigned integers
always 0
always 0xFFFFFFFF
0xFFFFFFFF for forward byte order,
0 for backward byte order
always 0
always 0xABCDEF08
version, currently 1
reserved
floating point type, 1 for IEEE 754
reserved
number of variables
header size, 128
reserved
offset of variable descriptor table from end of
header
reserved
Variable Data
After the header comes the variable data. Matrices are laid out in row-major order, and strings are
written with a null-terminating byte.
Member
Type
Description
off
len
size_t
size_t
offset of element data from beginning of string array data
length of element data, including null-terminating byte
On a 32-bit machine, a size_t is 4 bytes. On a 64-bit machine, it is 8 bytes.
Arrays are written with the orders (sizes) of each dimension followed by the array data. For
example, the following 2×3×4 array:
17-25
File I/O
For string arrays, an array of rows×columns struct satable’s is written out first, followed by the
string array data in row-major order with each element null terminated. A struct satable consists
of two members:
GAUSS User Guide
[1,1,1] through [1,3,4] =
1 2 3 4
5 6 7 8
9 10 11 12
[2,1,1] through [2,3,4] =
13 14 15 16
17 18 19 20
21 22 23 24
would be written out like this:
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24
Variable Structures
The variable data is followed by an array of variable descriptors. For each variable in the GDA,
there is a corresponding variable descriptor in this array. A variable descriptor is laid out as
follows:
Offset
Type
Description
0-3
4-7
8-11
12-15
16-19
32-bit unsigned integer
32-bit unsigned integer
32-bit unsigned integer
32-bit unsigned integer
32-bit unsigned integer
variable type
data type, 10 for 8 byte floating point
dimensions, used only for arrays
complex flag, 1 for real data, 0 for complex
size of pointer, indicates whether the variable was written
on a 32-bit or 64-bit platform
17-26
File I/O
Offset
Type
Description
20-23
32-bit unsigned integer
24-31
32-39
64-bit unsigned integer
64-bit unsigned integer
40-47
48-55
56-63
64-143
64-bit unsigned integer
64-bit unsigned integer
64-bit unsigned integer
string
huge flag, indicates whether the variable is larger than
INT MAX
rows for matrices and string arrays
columns for matrices and string arrays, length for strings,
including null-terminating byte
index of the variable in the GDA
offset of variable data from end of header
length of variable data in bytes
name of variable, null-terminated
The variable type (bytes 0-3) may be any of the following:
20
30
40
50
array
matrix
string
string array
The huge flag (bytes 20-23) is set to 1 if the variable size is greater than INT MAX, which is
defined as 2147483647. A variable for which the huge flag is set to 1 may not be read into GAUSS
on a 32-bit machine.
The variable index element (bytes 40-47) contains the index of the variable in the GDA. Although
the variable data is not necessarily ordered by index (see gdaUpdate), the variable descriptors are.
Therefore, the indices are always in ascending order.
17-27
File I/O
The size of pointer element (bytes 16-19) is the size of a pointer on the machine on which the
variable was written to the GDA. It will be set to 4 on 32-bit machines and 8 on 64-bit machines.
This element is used only for string array variables. If a GDA containing string arrays is created
on a 32-bit machine and then read on a 64-bit machine, or vice versa, then the size of pointer
element indicates how the members of the struct satable’s must be converted in order to be read
on the current machine.
Foreign Language Interface
18
The Foreign Language Interface (FLI) allows users to create functions written in C, FORTRAN, or
other languages, and call them from a GAUSS program. The functions are placed in dynamic
libraries (DLLs, also known as shared libraries or shared objects) and linked in at run-time as
needed. The FLI functions are:
Link and unlink dynamic libraries at run-time.
dllcall
Call functions located in dynamic libraries.
FLI
dlibrary
GAUSS recognizes a default dynamic library directory, a directory where it will look for your
dynamic-link libraries when you call dlibrary. You can specify the default directory in
gauss.cfg by setting dlib_path. As it is shipped, gauss.cfg specifies $(GAUSSDIR)/dlib as
the default directory.
18-1
GAUSS User Guide
18.1
Writing FLI Functions
Your FLI functions should be written to the following specifications:
1. Take 0 or more pointers to doubles as arguments.
This does not mean you cannot pass strings to an FLI function. Just recast the double
pointer to a char pointer inside the function.
2. Take those arguments either in a list or a vector.
3. Return an integer.
In C syntax, then, your functions would take one of the following forms:
1. int func(void);
2. int func(double *arg1 [[,double *arg2,. . .]]);
3. int func(double *arg[]);
Functions can be written to take a list of up to 100 arguments, or a vector (in C terms, a
1-dimensional array) of up to 1000 arguments. This does not affect how the function is called from
GAUSS; the dllcall statement will always appear to pass the arguments in a list. That is, the
dllcall statement will always look as follows:
dllcall func(a,b,c,d[[,e...]]);
For details on calling your function, passing arguments to it, getting data back, and what the return
value means, see dllcall in the GAUSS L R.
18-2
Foreign Language Interface
18.2
Creating Dynamic Libraries
The following describes how to build a dynamic library called hyp.dll (on Windows) or
libhyp.so (on UNIX/Linux) from the source file hyp.c.
As mentioned in the previous section, your FLI functions may take only pointers to doubles as
arguments. Therefore, you should define your FLI functions to be merely wrapper functions that
cast their arguments as necessary and then call the functions that actually do the work. This is
demonstrated in the source file hyp.c:
#include <stdio.h>
#include <stdlib.h>
#include <math.h>
/* This code is not meant to be efficient. It is meant
** to demonstrate the use of the FLI.
*/
/* this does all the work, not exported */
static int hypo(double *x, double *y, double *h, int r, int c)
{
double *wx;
double *wy;
double *dp;
double *sp1;
double *sp2;
int i, elems;
elems = r*c;
if ((wy = (double *)malloc(elems*sizeof(double))) == NULL)
{
18-3
FLI
/* malloc work arrays */
if ((wx = (double *)malloc(elems*sizeof(double))) == NULL)
return 30;
/* out of memory */
GAUSS User Guide
free(wx);
return 30;
/* out of memory */
}
dp = wx;
sp1 = x;
/* square x into work area wx */
for (i=0; i<elems; i++)
{
*dp = *sp1 * *sp1;
++sp1;
++dp;
}
dp = wy;
sp2 = y;
/* square y into work area wy */
for (i=0; i<elems; i++)
{
*dp = *sp2 * *sp2;
++sp2;
++dp;
}
dp = h;
sp1 = wx;
sp2 = wy;
/* compute hypotenuse into h which was allocated by GAUSS */
for (i=0; i<elems; i++)
{
*dp = sqrt(*sp1 + *sp2);
++sp1;
++sp2;
++dp;
18-4
Foreign Language Interface
}
/* free whatever you malloc */
free(wx);
free(wy);
return 0;
}
/* exported wrapper, all double * arguments, calls the real
** function with whatever data types it expects
*/
int hypotenuse(double *x, double *y, double *h,
double *r, double *c)
{
return hypo( x, y, h, (int)*r, (int)*c );
}
The following Makefiles contain the compile and link commands you would use to build the
dynamic library on various platforms. For explanations of the various flags used, see the
documentation for your compiler and linker.
Windows
hyp.dll: hyp.obj
link /dll /out:hyp.dll hyp.obj
FLI
hyp.obj: hyp.c
cl -c -MD -GX hyp.c
Solaris
$(CCOPTS) indicates any optional compilation flags you might add.
18-5
GAUSS User Guide
CCOPTIONS = -g -xsb -xarch=v9 -KPIC
CC = cc
libhyp.so: hyp.c
$(CC) -G $(CCOPTIONS) -o $@ hyp.c -lm
Linux
$(CCOPTS) indicates any optional compilation flags you might add.
CCOPTIONS = -g -O2 -lm -lc -shared
CC = gcc
libhyp.so: hyp.cpp
$(CC) $(CCOPTIONS) -o $@ hyp.c
For details on linking your dynamic library, see dlibrary in the GAUSS L R.
18-6
Data Loop
Data Transformations
19
GAUSS allows expressions that directly reference variables (columns) of a data set. This is done
within the context of a data loop:
dataloop infile outfile;
drop wagefac wqlec shordelt foobly;
csed = ln(sqrt(csed));
select csed > 0.35 and married $=\,= "y";
make chfac = hcfac + wcfac;
keep csed chfac stid recsum voom;
endata;
GAUSS translates the data loop into a procedure that performs the required operations, and then
calls the procedure automatically at the location (in your program) of the data loop. It does this by
translating your main program file into a temporary file and then executing the temporary file.
A data loop may be placed only in the main program file. Data loops in files that are #include’d
or autoloaded are not recognized.
19-1
GAUSS User Guide
19.1
Data Loop Statements
A data loop begins with a dataloop statement and ends with an endata statement. Inside a data
loop, the following statements are supported:
code
Create variable based on a set of logical expressions.
delete
Delete rows (observations) based on a logical expression.
drop
Specify variables NOT to be written to data set.
extern
Allow access to matrices and strings in memory.
keep
Specify variables to be written to output data set.
lag
Lag variables a number of periods.
listwise
Control deletion of missing values.
make
Create new variable.
outtyp
Specify output file precision.
recode
Change variable based on a set of logical expressions.
select
Select rows (observations) based on a logical expression.
vector
Create new variable from a scalar returning expression.
In any expression inside a data loop, all text symbols not immediately followed by a left
parenthesis ‘(’ are assumed to be data set variable (column) names. Text symbols followed by a
left parenthesis are assumed to be procedure names. Any symbol listed in an extern statement is
assumed to be a matrix or string already in memory.
19-2
19.2
Using Other Statements
All program statements in the main file and not inside a data loop are passed through to the
temporary file without modification. Program statements within a data loop that are preceded by a
‘#’ are passed through to the temporary file without modification. The user familiar with the code
generated in the temporary file can use this to do out-of-the-ordinary operations inside the data
loop.
19.3
Debugging Data Loops
The translator that processes data loops can be turned on and off. When the translator is on, there
are three distinct phases in running a program:
Translation
Translation of main program file to temporary file.
Compilation
Compilation of temporary file.
Execution
Execution of compiled code.
19.3.1
Translation Phase
In the translation phase, the main program file is translated into a temporary file. Each data loop is
translated into a procedure and a call to this procedure is placed in the temporary file at the same
location as the original data loop. The data loop itself is commented out in the temporary file. All
the data loop procedures are placed at the end of the temporary file.
Depending upon the status of line number tracking, error messages encountered in this phase will
be printed with the file name and line numbers corresponding to the main file.
19.3.2
Compilation Phase
In the compilation phase, the temporary file is compiled. Depending upon the status of line
number tracking, error messages encountered in this phase will be printed with the file name and
19-3
Data Loop
Data Transformations
GAUSS User Guide
line numbers corresponding to both the main file and the temporary file.
19.3.3
Execution Phase
In the execution phase, the compiled program is executed. Depending on the status of line number
tracking, error messages will include line number references from both the main file and the
temporary file.
19.4
Reserved Variables
The following local variables are created by the translator and used in the produced code:
x_cv
x_drop
x_fpin
x_fpout
x_i
x_in
x_iptr
x_keep
x_lval
x_lvar
x_n
x_name
x_ncol
x_nlag
x_nrow
x_ntrim
x_out
x_outtyp
x_plag
x_ptrim
x_shft
x_tname
x_vname
x_x
These variables are reserved, and should not be used within a dataloop... endata section.
19-4
20
GAUSS now includes a profiler, which enables you to determine exactly how much time your
programs are spending on each line and in each called procedure, thereby providing you with the
information you need to increase the efficiency of your programs. The GAUSS Profiler and
tcollect are both run from a command prompt window, not at a GAUSS prompt.
20.1
Using the GAUSS Profiler
There are two steps to using the GAUSS Profiler: collection and analysis.
20.1.1
Collection
To collect profiling information, you must run your GAUSS program in tcollect, an executable
shipped with GAUSS that is identical to tgauss except that it generates a file containing profiling
information each time it is run:
20-1
Profiler
The GAUSS Profiler
GAUSS User Guide
tcollect -b myfile.e
The output displayed by tcollect includes the name of the output file containing the profiling
information. tcollect output files have a gaussprof prefix and a .gco extension.
Note that running tcollect on long programs may generate a very large .gco output file. Thus
you may want to delete the .gco files on your machine regularly.
20.1.2
Analysis
To analyze the information stored in the tcollect output file, you must run the gaussprof
executable, which is also shipped with GAUSS, on that file. gaussprof produces an organized
report, displaying the time usage by procedure and by line.
Assuming that running myfile.e in tcollect produced an output file called
gaussprof_001.gco, you could analyze the results in that file as follows:
gaussprof gaussprof_001.gco
The syntax for gaussprof is:
gaussprof [flags] profile data file ...
where [flags] may be any of the following:
-p
profile procedure calls
-l
profile line numbers
-h
suppress headers
-sp order
procedure call sort order where order contains one or more of the folllowing:
20-2
The GAUSS Profiler
exclusive time
t
total time
c
number of times called
p
procedure name
a
ascending order
d
descending order (default)
Profiler
e
Columns are sorted all ascending or all descending.
-sl order
line number sort order where order contains one or more of the folllowing:
t
time spent on line
c
number of times line was executed
f
file name
l
line number
a
ascending order
d
descending order (default)
Columns are sorted all ascending or all descending.
The default, with no flags, is: -pl -sp dep -sl dtf.
20-3
Publication Quality Graphics
GAUSS Publication Quality Graphics (PQG) is a set of routines built on the graphics functions
in GraphiC by Scientific Endeavors Corporation.
The main graphics routines include xy, xyz, surface, polar and log plots, as well as histograms,
bar, and box graphs. Users can enhance their graphs by adding legends, changing fonts, and
adding extra lines, arrows, symbols and messages.
The user can create a single full size graph, inset a smaller graph into a larger one, tile a window
with several equally sized graphs or place several overlapping graphs in the window. Graphic
panel size and location are all completely under the user’s control.
21.1
General Design
GAUSS PQG consists of a set of main graphing procedures and several additional procedures and
global variables for customizing the output.
All of the actual output to the window happens during the call to these main routines:
21-1
PQG
21
GAUSS User Guide
bar
Bar graphs.
box
Box plots.
contour
Contour plots.
draw
Draw graphs using only global variables.
hist
Histogram.
histp
Percentage histogram.
histf
Histogram from a vector of frequencies.
loglog
Log scaling on both axes.
logx
Log scaling on X axis.
logy
Log scaling on Y axis.
polar
Polar plots.
surface
3-D surface with hidden line removal.
xy
Cartesian graph.
xyz
3-D Cartesian graph.
21.2
21.2.1
Using Publication Quality Graphics
Getting Started
There are four basic parts to a graphics program. These elements should be in any program that
uses graphics routines. The four parts are the header, data setup, graphics format setup, and
graphics call.
21-2
Publication Quality Graphics
Header
In order to use the graphics procedures, the pgraph library must be activated. This is done in the
library statement at the top of your program or command file. The next line in your program will
typically be a command to reset the graphics global variables to their default state. For example:
library mylib, pgraph;
graphset;
PQG
Data Setup
The data to be graphed must be in matrices. For example:
x = seqa(1,1,50);
y = sin(x);
Graphics Format Setup
Most of the graphics elements contain defaults that allow the user to generate a plot without
modification. These defaults, however, may be overridden by the user through the use of global
variables and graphics procedures. Some of the elements that may be configured by the user are
axes numbering, labeling, cropping, scaling, line and symbol sizes and types, legends, and colors.
Calling Graphics Routines
The graphics routines take as input the user data and global variables that have previously been
set. It is in these routines where the graphics file is created and displayed.
Following are three PQG examples. The first two programs are different versions of the same
graph. The variables that begin with _p are the global control variables used by the graphics
21-3
GAUSS User Guide
routines. (For a detailed description of these variables, see G C V, Section
21.6.
Example 1 The routine being called here is a simple XY plot. The entire window will be used.
Four sets of data will be plotted with the line and symbol attributes automatically selected. This
graph will include a legend, title, and a time/date stamp (time stamp is on by default):
library pgraph;
graphset;
x = seqa(.1,.1,100);
y = sin(x);
y = y ˜ y*.8 ˜ y*.6 ˜ y*.4;
_plegctl = 1;
title("Example xy Graph");
xy(x,y);
/* activate PGRAPH library */
/* reset global variables */
/* generate data */
/*
/*
/*
/*
4 curves plotted against x */
legend on */
Main title */
Call to main routine */
Example 2 Here is the same graph with more of the graphics format controlled by the user. The
first two data sets will be plotted using symbols at data points only (observed data); the data points
in the second two sets will be connected with lines (predicted results):
library pgraph;
graphset;
x = seqa(.1,.1,100);
y = sin(x);
y = y ˜ y*.8 ˜ y*.6 ˜ y*.4;
_pdate = "";
_plctrl = { 1, 1, 0, 0 };
_pltype = { 1, 2, 6, 6 };
_pstype = { 1, 2, 0, 0 };
_plegctl= { 2, 3, 1.7, 4.5 };
_plegstr= "Sin wave 1.\0"\
"Sin wave .8\0"\
"Sin wave .6\0"\
"Sin wave .4";
ylabel("Amplitude");
21-4
/* activate PGRAPH library */
/* reset global variables */
/* generate data */
/*
/*
/*
/*
/*
/*
/*
4 curves plotted against x */
date is not printed */
2 curves w/symbols, 2 without */
dashed, dotted, solid lines */
symbol types circles, squares */
legend size and locations */
4 lines legend text */
/* Y axis label */
Publication Quality Graphics
xlabel("X Axis");
title("Example xy Graph");
xy(x,y);
/* X axis label */
/* main title */
/* call to main routine */
Example 3 In this example, two graphics panels are drawn. The first is a full-sized surface
representation, and the second is a half-sized inset containing a contour of the same data located in
the lower left corner of the window:
/* activate pgraph library */
PQG
library pgraph;
/* Generate data for surface and contour plots */
x = seqa(-10,0.1,71)’;
/* note x is a row vector */
y = seqa(-10,0.1,71);
/* note y is a column vector */
z = cos(5*sin(x) - y);
/* z is a 71x71 matrix */
begwind;
makewind(9,6.855,0,0,0);
makewind(9/2,6.855/2,1,1,0);
/* initialize graphics windows */
/* first window full size */
/* second window inset to first */
setwind(1);
graphset;
_pzclr = { 1, 2, 3, 4 };
title("cos(5*sin(x) - y)");
xlabel("X Axis");
ylabel("Y Axis");
scale3d(miss(0,0),miss(0,0),-5|5);
surface(x,y,z);
/*
/*
/*
/*
/*
/*
/*
/*
activate first window */
reset global variables */
set Z level colors */
set main title */
set X axis label */
set Y axis label */
scale Z axis */
call surface routine */
nextwind;
graphset;
_pzclr = { 1, 2, 3, 4 };
_pbox = 15;
contour(x,y,z);
/*
/*
/*
/*
/*
activate second window. */
reset global variables */
set Z level colors */
white border */
call contour routine */
endwind;
/* Display windows */
21-5
GAUSS User Guide
While the structure has changed somewhat, the four basic elements of the graphics program are all
here. The additional routines begwind, endwind, makewind, nextwind, and setwind are all
used to control the graphic panels.
As Example 3 illustrates, the code between graphic panel functions (that is, setwind or
nextwind) may include assignments to global variables, a call to graphset, or may set up new
data to be passed to the main graphics routines.
You are encouraged to run the example programs supplied with GAUSS. Analyzing these
programs is perhaps the best way to learn how to use the PQG system. The example programs are
located on the examples subdirectory.
21.2.2
Graphics Coordinate System
PQG uses a 4190×3120 pixel resolution grid on a 9.0×6.855-inch printable area. There are three
units of measure supported with most of the graphics global elements:
Inch Coordinates
Inch coordinates are based on the dimensions of the full-size 9.0×6.855-inch output page. The
origin is (0,0) at the lower left corner of the page. If the picture is rotated, the origin is at the upper
left. (For more information, see I U  G P, Section 21.3.5.)
Plot Coordinates
Plot coordinates refer to the coordinate system of the graph in the units of the user’s X, Y and Z
axes.
Pixel Coordinates
Pixel coordinates refer to the 4096×3120 pixel coordinates of the full-size output page. The origin
is (0,0) at the lower left corner of the page. If the picture is rotated, the origin is at the upper left.
21-6
Publication Quality Graphics
21.3
Graphic Panels
Multiple graphic panels for graphics are supported. These graphic panels allow the user to display
multiple graphs on one window or page.
A graphic panel is any rectangular subsection of the window or page. Graphc panels may be any
size and position on the window and may be tiled or overlapping, transparent or nontransparent.
21.3.1
Tiled Graphic Panels
This example will divide the window into six equally sized graphic panels. There will be two rows
of three graphic panels–three graphic panels in the upper half of the window and three in the lower
half. The attribute value of 0 is arbitrary since there are no other graphic panels beneath them.
window(nrows,ncols,attr);
window(2,3,0);
21.3.2
Overlapping Graphic Panels
Overlapping graphic panels are laid on top of one another as they are created, much as if you were
using the cut and paste method to place several graphs together on one page. An overlapping
graphic panel is created with the makewind command.
In this example, makewind will create an overlapping graphic panel that is 4 inches wide by 2.5
inches tall, positioned 1 inch from the left edge of the page and 1.5 inches from the bottom of the
page. It will be nontransparent:
makewind(hsize,vsize,hpos,vpos,attr);
21-7
PQG
Tiled graphic panels do not overlap. The window can easily be divided into any number of tiled
graphic panels with the window command. window takes three parameters: number of rows,
number of columns, and graphic panel attribute (1=transparent, 0=nontransparent).
GAUSS User Guide
window(2,3,0);
makewind(4,2.5,1,1.5,0);
21.3.3
Nontransparent Graphic Panels
A nontransparent graphic panel is one that is blanked before graphics information is written to it.
Therefore, information in any previously drawn graphic panels that lie under it will not be visible.
21.3.4
Transparent Graphic Panels
A transparent graphic panel is one that is not blanked, allowing the graphic panel beneath it to
“show through”. Lines, symbols, arrows, error bars, and other graphics objects may extend from
one graphic panel to the next by using transparent graphic panels. First, create the desired graphic
panel configuration. Then create a full-window, transparent graphic panel using the makewind or
window command. Set the appropriate global variables to position the desired object on the
transparent graphic panel. Use the draw procedure to draw it. This graphic panel will act as a
transparent “overlay” on top of the other graphic panels. Transparent graphic panels can be used to
add text or to superimpose one graphic panel on top of another.
21.3.5
Using Graphic Panel Functions
The following is a summary of the graphic panel functions:
begwind
Graphic panel initialization procedure.
endwind
End graphic panel manipulations, display graphs.
window
Partition window into tiled graphic panels.
makewind
Create graphic panel with specified size and position.
setwind
Set to specified graphic panel number.
21-8
Publication Quality Graphics
nextwind
Set to next available graphic panel number.
getwind
Get current graphic panel number.
savewind
Save graphic panel configuration to a file.
loadwind
Load graphic panel configuration from a file.
This example creates four tiled graphic panels and one graphic panel that overlaps the other four:
window(2,2,0);
PQG
library pgraph;
graphset;
begwind;
/* Create four tiled graphic panels
(2 rows, 2 columns) */
xsize = 9/2;
/* Create graphic panel that overlaps the
tiled graphic panels */
ysize = 6.855/2;
makewind(xsize,ysize,xsize/2,ysize/2,0);
x = seqa(1,1,1000);
y = (sin(x) + 1) * 10.;
setwind(1);
xy(x,y);
nextwind;
logx(x,y);
nextwind;
logy(x,y);
nextwind;
loglog(x,y);
nextwind;
bar(x,y);
endwind;
/* Create X data */
/* Create Y data */
/* Graph #1, upper left corner */
/* Graph #2, upper right corner */
/* Graph #3, lower left corner */
/* Graph #4, lower right corner */
/* Graph #5, center, overlayed */
/* End graphic panel processing,
display graph */
21-9
GAUSS User Guide
21.3.6
Inch Units in Graphic Panels
Some global variables allow coordinates to be input in inches. If a coordinate value is in inches
and is being used in a graphic panel, that value will be scaled to “graphic panel inches” and
positioned relative to the lower left corner of the graphic panel. A “graphic panel inch” is a true
inch in size only if the graphic panel is scaled to the full window, otherwise X coordinates will be
scaled relative to the horizontal graphic panel size and Y coordinates will be scaled relative to the
vertical graphic panel size.
21.3.7
Saving Graphic Panel Configurations
The functions savewind and loadwind allow the user to save graphic panel configurations. Once
graphic panels are created (using makewind and window), savewind may be called. This will
save to disk the global variables containing information about the current graphic panel
configuration. To load this configuration again, call loadwind. (See loadwind in the GAUSS
L R.
21.4
Graphics Text Elements
Graphics text elements, such as titles, messages, axes labels, axes numbering, and legends, can be
modified and enhanced by changing fonts and by adding superscripting, subscripting, and special
mathematical symbols.
To make these modifications and enhancements, the user can embed “escape codes” in the text
strings that are passed to title, xlabel, ylabel and asclabel or assigned to _pmsgstr and
_plegstr.
The escape codes used for graphics text are:
\000
[
]
@
\20n
21-10
String termination character (null byte).
Enter superscript mode, leave subscript mode.
Enter subscript mode, leave superscript mode.
Interpret next character as literal.
Select font number n. (see S F, following).
Publication Quality Graphics
The escape code \L (or \l) can be embedded into title strings to create a multiple line title:
title("This is the first line\lthis is the second line");
A null byte \000 is used to separate strings in _plegstr and _pmsgstr:
_pmsgstr = "First string\000Second string\000Third string";
PQG
or
_plegstr = "Curve 1\000Curve 2";
Use [..] to create the expression M(t) = E(etx ):
_pmsgstr = "M(t) = E(e[tx])";
Use @ to generate [ and ] in an X axis label:
xlabel("Data used for x is: data@[.,1 2 3@]");
21.4.1
Selecting Fonts
Four fonts are supplied with the Publication Quality Graphics system. They are Simplex,
Complex, Simgrma, and Microb. (For a list of the characters available in each font, see Appendix
A.)
Fonts are loaded by passing to the fonts procedure a string containing the names of all fonts to be
loaded. For example, this statement will load all four fonts:
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GAUSS User Guide
fonts("simplex complex microb simgrma");
The fonts command must be called before any of the fonts can be used in text strings. A font can
then be selected by embedding an escape code of the form “\20n” in the string that is to be written
in the new font. The n will be 1, 2, 3 or 4, depending on the order in which the fonts were loaded
in fonts. If the fonts were loaded as in the previous example, the escape characters for each
would be:
\201
\202
\203
\204
Simplex
Complex
Microb
Simgrma
The following example demonstrates how to select a font for use in a string:
title("\201This is the title using Simplex font");
xlabel("\202This is the label for X using Complex font");
ylabel("\203This is the label for Y using Microb font");
Once a font is selected, all succeeding text will use that font until another font is selected. If no
fonts are selected by the user, a default font (Simplex) is loaded and selected automatically for all
text work.
21.4.2
Greek and Mathematical Symbols
The following examples illustrate the use of the Simgrma font; they assume that Simgrma was the
fourth font loaded. (For the available Simgrma characters and their numbers, see Appendix A.)
The Simgrma characters are specified by either:
1. The character number, preceeded by a “\”.
2. The regular text character with the same number.
21-12
Publication Quality Graphics
R
For example, to get an integral sign “ ” in Simgrma, embed either a “\044” or a “,” in a string
that has been set to use the Simgrma font.
To produce the title f (x) = sin2 (πx), the following title string should be used:
title("\201f(x) = sin[2](\204p\201x)");
The “p” (character 112) corresponds to “π” in Simgrma.
lab = "\2010 \204p\201/4 \204p\201/2
asclabel(lab,0);
xtics(0,pi,pi/4,1);
3\204p\201/4 \204p";
xtics is used to make sure that major tick marks are placed in the appropriate places.
This example will number the X axis tick marks with the labels µ−2 , µ−1 , 1, µ, and µ2 :
lab = "\204m\201[-2] \204m\201[-1] 1 \204m m\201[2]";
asclabel(lab,0);
This example illustrates the use of several of the special Simgrma symbols:
_pmsgstr =
"\2041\2011/2\204p ,\201e[-\204m[\2012]\201/2]d\204m";
This produces:
√
1/2π
Z
e−µ /2 dµ
2
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PQG
To number the major X axis tick marks with multiples of π/4, the following could be passed to
asclabel:
GAUSS User Guide
21.5
Colors
0
1
2
3
4
5
6
7
21.6
Black
Blue
Green
Cyan
Red
Magenta
Brown
Grey
8
9
10
11
12
13
14
15
Dark Grey
Light Blue
Light Green
Light Cyan
Light Red
Light Magenta
Yellow
White
Global Control Variables
The following global variables are used to control various graphics elements. Default values are
provided. Any or all of these variables can be set before calling one of the main graphing routines.
The default values can be modified by changing the declarations in pgraph.dec and the
statements in the procedure graphset in pgraph.src. graphset can be called whenever the
user wants to reset these variables to their default values.
_pageshf
2×1 vector, the graph will be shifted to the right and up if this is not 0. If this is
0, the graph will be centered on the output page. Default is 0.
Note: Used internally. (For the same functionality, see makewind in the
GAUSS L R.) This is used by the graphic panel routines. The
user must not set this when using the graphic panel procedures.
_pagesiz
2×1 vector, size of the graph in inches on the printer output. Maximum size is
9.0×6.855 inches (unrotated) or 6.855×9.0 inches (rotated). If this is 0, the
maximum size will be used. Default is 0.
Note: Used internally. (For the same functionality, see makewind in the
GAUSS L R). This is used by the graphic panel routines. The
user must not set this when using the graphic panel procedures.
_parrow
21-14
M×11 matrix, draws one arrow per row of the input matrix (for total of M
arrows). If scalar zero, no arrows will be drawn.
Publication Quality Graphics
[M,1] x starting point.
[M,2] y starting point.
[M,3] x ending point.
[M,4] y ending point.
[M,5] ratio of the length of the arrow head to half its width.
[M,6] size of arrow head in inches.
[M,7] type and location of arrow heads. This integer number will be
interpreted as a decimal expansion mn, for example: if 10, then m = 1, n =
0.
PQG
m, type of arrow head:
0
1
2
3
solid
empty
open
closed
n, location of arrow head:
0
1
2
none
at the final end
at both ends
[M,8] color of arrow, see C, Section 21.5.
[M,9] coordinate units for location:
1
2
3
x,y starting and ending locations in plot coordinates
x,y starting and ending locations in inches
x,y starting and ending locations in pixels
[M,10] line type:
1
2
3
4
5
6
dashed
dotted
short dashes
closely spaced dots
dots and dashes
solid
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GAUSS User Guide
[M,11] controls thickness of lines used to draw arrow. This value may be zero
or greater. A value of zero is normal line width.
To create two single-headed arrows, located using inches, use
_parrow = {
_parrow3
1
3
1
4
2
2
2
2
3
3
0.2
0.2
11
11
10
10
2
2
6
6
0,
0 };
M×12 matrix, draws one 3-D arrow per row of the input matrix (for a total of M
arrows). If scalar zero, no arrows will be drawn.
[M,1] x starting point in 3-D plot coordinates.
[M,2] y starting point in 3-D plot coordinates.
[M,3] z starting point in 3-D plot coordinates.
[M,4] x ending point in 3-D plot coordinates.
[M,5] y ending point in 3-D plot coordinates.
[M,6] z ending point in 3-D plot coordinates.
[M,7] ratio of the length of the arrow head to half its width.
[M,8] size of arrow head in inches.
[M,9] type and location of arrow heads. This integer number will be
interpreted as a decimal expansion mn. For example: if 10, then m = 1, n
= 0.
m, type of arrow head:
0
1
2
3
solid
empty
open
closed
n, location of arrow head:
0
1
2
none
at the final end
at both ends
[M,10] color of arrow, see C, Section 21.5.
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Publication Quality Graphics
[M,11] line type:
1
2
3
4
5
6
dashed
dotted
short dashes
closely spaced dots
dots and dashes
solid
[M,12] controls thickness of lines used to draw arrow. This value may be zero
or greater. A value of zero is normal line width.
PQG
To create two single-headed arrows, located using plot coordinates, use
_parrow3 = {
_paxes
1
3
1
4
1
5
2
2
2
2
2
2
3
3
0.2
0.2
11
11
10
10
6
6
0,
0 };
scalar, 2×1, or 3×1 vector for independent control for each axis. The first
element controls the X axis, the second controls the Y axis, and the third (if set)
controls the Z axis. If 0 the axis will not be drawn. Default is 1.
If this is a scalar, it will be expanded to that value.
For example:
_paxes = { 1, 0 }; /* turn X axis on, Y axis off */
_paxes = 0;
/* turn all axes off */
_paxes = 1;
/* turn all axes on */
_paxht
scalar, size of axes labels in inches. If 0, a default size will be computed.
Default is 0.
_pbartyp
1×2 or K×2 matrix. Controls bar shading and colors in bar graphs and
histograms.
The first column controls the bar shading:
0
no shading
1
dots
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GAUSS User Guide
2
vertical cross-hatch
3
diagonal lines with positive slope
4
diagonal lines with negative slope
5
diagonal cross-hatch
6
solid
The second column controls the bar color, see C, Section 21.5.
_pbarwid
scalar, width of bars in bar graphs and histograms. The valid range is 0-1. If 0,
the bars will be a single pixel wide. If 1, the bars will touch each other. Default
is 0.5, so the bars take up about half the space open to them.
_pbox
scalar, draws a box (border) around the entire graph. Set to desired color of box
to be drawn. Use 0 if no box is desired. Default is 0.
_pboxctl
5×1 vector, controls box plot style, width, and color. Used by procedure box
only.
[1]
box width between 0 and 1. If 0, the box plot is drawn as two vertical
lines representing the quartile ranges with a filled circle representing the
50th percentile.
[2]
box color, see C, Section 21.5. If 0, the colors may be individually
controlled using global variable _pcolor.
[3]
min/max style for the box symbol. One of the following:
1
2
3
21-18
minimum and maximum taken from the actual limits of the data.
Elements 4 and 5 are ignored.
statistical standard with the minimum and maximum calculated
according to interquartile range as follows:
intqrange = 75th − 25th
min
= 25th − 1.5 intqrange
max
= 75th + 1.5 intqrange
Elements 4 and 5 are ignored.
minimum and maximum percentiles taken from elements 4 and 5.
[4]
minimum percentile value (0-100) if _pboxctl[3] = 3.
[5]
maximum percentile value (0-100) if _pboxctl[3] = 3.
Publication Quality Graphics
_pboxlim
5×M output matrix containing computed percentile results from procedure box.
M corresponds to each column of input y data.
[1,M] minimum whisker limit according to _pboxctl[3].
[2,M] 25th percentile (bottom of box).
[3,M] 50th percentile (median).
[4,M] 75th percentile (top of box).
[5,M] maximum whisker limit according to _pboxctl[3].
scalar or K×1 vector, colors for main curves in xy, xyz and log graphs. To use
a single color set for all curves set this to a scalar color value. If 0, use default
colors. Default is 0.
The default colors come from a global vector called _pcsel. This vector can be
changed by editing pgraph.dec to change the default colors, see C,
Section 21.5 (_pcsel is not documented elsewhere).
_pcrop
scalar or 1×5 vector, allows plot cropping for different graphic elements to be
individually controlled. Valid values are 0 (disabled) or 1 (enabled). If cropping
is enabled, any graphical data sent outside the axes area will not be drawn. If
this is a scalar, it is expanded to a 1×5 vector using the given value for all
elements. All cropping is enabled by default.
[1]
crop main curves/symbols.
[2]
crop lines generated using _pline.
[3]
crop arrows generated using _parrow.
[4]
crop circles/arcs generated using _pline.
[5]
crop symbols generated using _psym.
This example will crop main curves, and lines and circles drawn by _pline.
_pcrop = { 1 1 0 1 0 };
_pcross
scalar. If 1, the axes will intersect at the (0,0) X-Y location if it is visible.
Default is 0, meaning the axes will be at the lowest end of the X-Y coordinates.
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PQG
_pcolor
GAUSS User Guide
_pdate
date string. If this contains characters, the date will be appended and printed.
The default is set as follows (the first character is a font selection escape code):
_pdate = "\201GAUSS
";
If this is set to a null string, no date will be printed. (For more information on
using fonts within strings, see G T E, Section 21.4.
_perrbar
M×9 matrix, draws one error bar per row of the input matrix. If scalar 0, no
error bars will be drawn. Location values are in plot coordinates.
[M,1] x location.
[M,2] left end of error bar.
[M,3] right end of error bar.
[M,4] y location.
[M,5] bottom of error bar.
[M,6] top of error bar.
[M,7] line type:
1
2
3
4
5
6
dashed
dotted
short dashes
closely spaced dots
dots and dashes
solid
[M,8] color, see C, Section 21.5.
[M,9] line thickness.. This value may be 0 or greater. A value of 0 is normal
line width.
To create one error bar using solid lines, use
_perrbar = { 1
_pframe
21-20
0
2
2
1
3
6
2
0 };
2×1 vector, controls frame around axes area. On 3-D plots this is a cube
surrounding the 3-D workspace.
Publication Quality Graphics
[1]
1
0
frame on
frame off
[2]
1
0
tick marks on frame
no tick marks
The default is a frame with tick marks.
_pgrid
2×1 vector to control grid.
[1]
grid through tick marks:
[2]
no grid
dotted grid
fine dotted grid
solid grid
PQG
0
1
2
3
grid subdivisions between major tick marks:
0
1
2
no subdivisions
dotted lines at subdivisions
tick marks only at subdivisions
The default is no grid and tick marks at subdivisions.
_plctrl
scalar or K×1 vector to control whether lines and/or symbols will be displayed
for the main curves. This also controls the frequency of symbols on main
curves. The number of rows (K) is equal to the number of individual curves to
be plotted in the graph. Default is 0.
0
draw line only.
>0
draw line and symbols every _plctrl points.
<0
draw symbols only every _plctrl points.
−1
all of the data points will be plotted with no connecting lines.
This example draws a line for the first curve, draws a line and plots a symbol
every 10 data points for the second curve, and plots symbols only every 5 data
points for the third curve:
_plctrl = { 0, 10, -5 };
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GAUSS User Guide
_plegctl
scalar or 1×4 vector, legend control variable.
If scalar 0, no legend is drawn (default). If nonzero scalar, create legend in the
default location in the lower right of the page.
If 1×4 vector, set as follows:
[1]
legend position coordinate units:
1
2
3
coordinates are in plot coordinates
coordinates are in inches
coordinates are in pixel
[2]
legend text font size, where 1 <= size <= 9. Default is 5.
[3]
x coordinate of lower left corner of legend box.
[4]
y coordinate of lower left corner of legend box.
This example puts a legend in the lower right corner:
_plegctl = 1;
This example creates a smaller legend and positions it 2.5 inches from the left
and 1 inch from the bottom.
_plegctl = { 2 3 2.5 1 };
_plegstr
string, legend entry text. Text for multiple curves is separated by a null byte
(“\000”).
For example:
_plegstr = "Curve 1\000Curve 2\000Curve 3";
_plev
M×1 vector, user-defined contour levels for contour. Default is 0. (See
contour in the GAUSS L R.)
_pline
M×9 matrix, to draw lines, circles, or radii. Each row controls one item to be
drawn. If this is a scalar zero, nothing will be drawn. Default is 0.
[M,1] item type and coordinate system:
21-22
Publication Quality Graphics
1
2
3
4
5
6
7
line in plot coordinates
line in inch coordinates
line in pixel coordinates
circle in plot coordinates
circle in inch coordinates
radius in plot coordinates
radius in inch coordinates
[M,2] line type:
dashed
dotted
short dashes
closely spaced dots
dots and dashes
solid
PQG
1
2
3
4
5
6
[M,3-7] coordinates and dimensions:
if item type is line (1<=_pline[M,1]<=3):
[M,3]
[M,4]
[M,5]
[M,6]
[M,7]
x starting point.
y starting point.
x ending point.
y ending point.
0 if this is a continuation of a curve, 1 if this begins a new curve.
if item type is circle (_pline[M,1] = 4 or _pline[M,1] = 5):
[M,3]
[M,4]
[M,5]
[M,6]
[M,7]
x center of circle.
y center of circle.
radius.
starting point of arc in radians.
ending point of arc in radians.
if item type is radius (_pline[M,1] = 6 or _pline[M,1] = 7):
[M,3] x center of circle.
[M,4] y center of circle.
[M,5] beginning point of radius, 0 is the center of the circle.
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GAUSS User Guide
[M,6] ending point of radius.
[M,7] angle in radians.
[M,8] color, see C, Section 21.5.
[M,9] controls line thickness. This value may be zero or greater. A value of
zero is normal line width.
_pline3d
M×9 matrix. Allows extra lines to be added to an xyz or surface graph in 3-D
plot coordinates.
[M,1] x starting point.
[M,2] y starting point.
[M,3] z starting point.
[M,4] x ending point.
[M,5] y ending point.
[M,6] z ending point.
[M,7] color.
[M,8] line type:
1
2
3
4
5
6
dashed
dotted
short dashes
closely spaced dots
dots and dashes
solid
[M,9] line thickness, 0 = normal width.
[M,10] hidden line flag, 1 = obscured by surface, 0 = not obscured.
_plotshf
2×1 vector, distance of plot from lower left corner of output page in inches.
[1]
x distance.
[2]
y distance.
If scalar 0, there will be no shift. Default is 0.
Note: Used internally. (For the same functionality, see axmargin in the
GAUSS L R.) This is used by the graphic panel routines. The
user must not set this when using the graphic panel procedures.
21-24
Publication Quality Graphics
_plotsiz
2×1 vector, size of the axes area in inches. If scalar 0, the maximum size will
be used.
Note: Used internally. (For the same functionality, see axmargin in the
GAUSS L R.) This is used by the graphic panel routines. The
user must not set this when using the graphic panel procedures.
_pltype
scalar or K×1 vector, line type for the main curves. If this is a nonzero scalar, all
lines will be this type. If scalar 0, line types will be default styles. Default is 0.
dashed
2
dotted
3
short dashes
4
closely spaced dots
5
dots and dashes
6
solid
PQG
1
The default line types come from a global vector called _plsel. This vector
can be changed by editing pgraph.dec to change the default line types
(_plsel is not documented elsewhere.)
_plwidth
scalar or K×1 vector, line thickness for main curves. This value may be zero or
greater. A value of zero is normal (single pixel) line width. Default is 0.
_pmcolor
9×1 vector, color values to use for plot, see C, Section 21.5.
[1]
axes.
[2]
axes numbers.
[3]
X axis label.
[4]
Y axis label.
[5]
Z axis label.
[6]
title.
[7]
box.
[8]
date.
[9]
background.
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GAUSS User Guide
If this is scalar, it will be expanded to a 9×1 vector.
_pmsgctl
L×7 matrix of control information for printing the strings contained in
_pmsgstr.
[L,1] horizontal location of lower left corner of string.
[L,2] vertical location of lower left corner of string.
[L,3] character height in inches.
[L,4] angle in degrees to print string. This may be -180 to 180 relative to the
positive X axis.
[L,5] location coordinate system.
1
2
location of string in plot coordinates
location of string in inches
[L,6] color.
[L,7] font thickness, may be 0 or greater. If 0 use normal line width.
_pmsgstr
string, contains a set of messages to be printed on the plot. Each message is
separated from the next by a null byte (\000). The number of messages must
correspond to the number of rows in the _pmsgctl control matrix. This can be
created as follows:
_pmsgstr = "Message one.\000Message two.";
_pnotify
_pnum
scalar, controls window output during the creation of the graph. Default is 1.
0
no activity to the window while writing .tkf file
1
display progress as fonts are loaded, and .tkf file is being generated
scalar, 2×1 or 3×1 vector for independent control for axes numbering. The first
element controls the X axis numbers, the second controls the Y axis numbers,
and the third (if set) controls the Z axis numbers. Default is 1.
If this value is scalar, it will be expanded to a vector.
21-26
0
no axes numbers displayed
1
axes numbers displayed, vertically oriented on axis
Publication Quality Graphics
2
axes numbers displayed, horizontally oriented on axis
For example:
_pnum = { 0, 2 }; /* no X axis numbers, */
/* horizontal on Y axis */
scalar, size of axes numbers in inches. If 0, a size of .13 will be used. Default is
0.
_protate
scalar. If 0, no rotation, if 1, plot will be rotated 90 degrees. Default is 0.
_pscreen
scalar. If 1, display graph in window, if 0, do not display graph in window.
Default is 1.
_psilent
scalar. If 0, a beep will sound when the graph is finished drawing to the
window. Default is 1 (no beep).
_pstype
scalar or K×1 vector, controls symbol used at data points. To use a single
symbol type for all points, set this to one of the following scalar values:
1
2
3
4
5
6
7
circle
square
triangle
plus
diamond
inverted triangle
star
8
9
10
11
12
13
14
solid circle
solid square
solid triangle
solid plus
solid diamond
solid inverted triangle
solid star
If this is a vector, each line will have a different symbol. Symbols will repeat if
there are more lines than symbol types. Default is 0 (no symbols are shown).
_psurf
2×1 vector, controls 3-D surface characteristics.
[1]
if 1, show hidden lines. Default is 0.
[2]
color for base, see C, Section 21.5. The base is an outline of the X-Y
plane with a line connecting each corner to the surface. If 0, no base is
drawn. Default is 7.
21-27
PQG
_pnumht
GAUSS User Guide
_psym
M×7 matrix, M extra symbols will be plotted.
[M,1] x location.
[M,2] y location.
[M,3] symbol type, see _pstype earlier.
[M,4] symbol height. If this is 0, a default height of 5.0 will be used.
[M,5] symbol color, see C, Section 21.5.
[M,6] type of coordinates:
1
2
plot coordinates
inch coordinates
[M,7] line thickness. A value of zero is normal line width.
_psym3d
M×7 matrix for plotting extra symbols on a 3-D (surface or xyz) graph.
[M,1] x location in plot coordinates.
[M,2] y location in plot coordinates.
[M,3] z location in plot coordinates.
[M,4] symbol type, see _pstype earlier.
[M,5] symbol height. If this is 0, a default height of 5.0 will be used.
[M,6] symbol color, see C, Section 21.5.
[M,7] line thickness. A value of 0 is normal line width.
Use _psym for plotting extra symbols in inch coordinates.
_psymsiz
scalar or K×1 vector, symbol size for the symbols on the main curves. This is
NOT related to _psym. If 0, a default size of 5.0 is used.
_ptek
string, name of Tektronix format graphics file. This must have a .tkf
extension. If this is set to a null string, the graphics file will be suppressed. The
default is graphic.tkf.
_pticout
scalar. If 1, tick marks point outward on graphs. Default is 0.
_ptitlht
scalar, the height of the title characters in inches. If this is 0, a default height of
approx. 0.13 inch will be used.
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Publication Quality Graphics
string, the graphics version number.
_pxpmax
scalar, the maximum number of places to the right of the decimal point for the
X axis numbers. Default is 12.
_pxsci
scalar, the threshold in digits above which the data for the X axis will be scaled
and a power of 10 scaling factor displayed. Default is 4.
_pypmax
scalar, the maximum number of places to the right of the decimal point for the
Y axis numbers. Default is 12.
_pysci
scalar, the threshold in digits above which the data for the Y axis will be scaled
and a power of 10 scaling factor displayed. Default is 4.
_pzclr
scalar, row vector, or K×2 matrix, Z level color control for procedures surface
and contour. (See surface in the GAUSS L R.)
_pzoom
1×3 row vector, magnifies the graphics display for zooming in on detailed areas
of the graph. If scalar 0, no magnification is performed. Default is 0.
[1]
magnification value. 1 is normal size.
[2]
horizontal center of zoomed plot (0-100).
[3]
vertical center of zoomed plot (0-100).
To see the upper left quarter of the screen magnified 2 times use:
_pzoom = { 2 25 75 };
_pzpmax
scalar, the maximum number of places to the right of the decimal point for the
Z axis numbers. Default is 3.
_pzsci
scalar, the threshold in digits above which the data for the Z axis will be scaled
and a power of 10 scaling factor displayed. Default is 4.
21-29
PQG
_pversno
Graphics Editor
Graphics
Editor
22.1
22
Introduction to the Graphics Editor
The GAUSS graphics editor is a utility for composing pages containing GAUSS graphics files. Its
primary purpose is to provide the user with a toolbox for creating and annotating graphs created
by GAUSS using all of the fonts available on your Windows system. It is not meant to be a
full-featured publishing tool but rather a supplemental utility for dynamically importing and easily
arranging multiple graphics files on a single page.
22.1.1
Overview
The graphics editor allows the user to interactively create any number of graphical objects for
composing documents. It is launched by selecting Tools from the GAUSS menu bar, then
Graphics Editor, or by clicking on the Graphics Editor icon on the GAUSS toolbar.
Once the document has been created, it may be saved for later modification. All of the objects and
their respective properties contained in the document are preserved. The document may also be
exported to other formats.
22-1
GAUSS User Guide
22.2
Graphics Editor Workspace
The graphics editor workspace is a window allowing access to a single page with tools for
composing the document. The page is defined by user-defined properties such as page orientation
and margin settings.
It provides a dialog bar for user-selection of the current pen and brush properties.
Zoom capability is provided for detailed accuracy and accomodating a wide-variety of computer
display resolutions.
Figure 22.1: Graphics Editor Workspace
22.2.1
Toolbar
The toolbar is displayed across the top of the application window, below the menu bar. The toolbar
provides quick mouse access to many tools used in the graphics editor.
22-2
Graphics Editor
To hide or display the toolbar, choose Toolbar from the View menu (ALT, V, T).
Figure 22.2: Graphics Editor Toolbar
22.2.2
Status Bar
The status bar is displayed at the bottom of the graphics editor window. To display or hide the
status bar, use the Status Bar command in the View menu.
In addition, the status bar provides short hints while using the graphical interface such as defining,
sizing, and moving objects.
Figure 22.3: Graphics Editor Status Bar
Indicator Description
The remaining status bar panes indicate the following:
22-3
Graphics
Editor
The left area of the status bar describes actions of menu items as you use the arrow keys to
navigate through menus. This area similarly shows messages that describe the actions of toolbar
buttons as you depress them, before releasing them. If after viewing the description of the toolbar
command you wish not to execute the command, then release the mouse button while the pointer
is off the toolbar button.
GAUSS User Guide
The x/y mouse position on the page (in units specified in the View Properties menu).
CAPS indicates the CAPS LOCK key is latched down.
NUM indicates the NUM LOCK key is latched down.
SCRL indicates the SCROLL LOCK key is latched down.
22.2.3
File menu commands
The File menu offers the following commands:
New
Opens a new, untitled document (CTRL+N).
Open
Opens an existing document in a new window (CTRL+O).
Import
Imports a file of another format. Currently only the GAUSS graphics format
.tkf is supported.
Save
Saves the active document to its current name and directory. When you save
a document for the first time, the graphics editor displays the Save As dialog
box so you can name your document (CTRL+S). If you want to change the
name and directory of an existing document before saving it, choose the
Save As command.
Save As
Saves and names the active document. The graphics editor displays the Save
As dialog box so you can name your document.
Print
Prints a document. This command presents a Print dialog box where you
may specify the ranges of pages to be printed, the number of copies, the
destination printer, and other printer setup options (CTRL+P).
Print Preview
Displays the active document as it would appear when printed. When you
choose this command, the main window will be replaced with a print
preview window in which one or two pages will be displayed in their printed
format. The print preview toolbar offers you the option to view either one or
two pages at a time, move back and forth through the document, zoom in
and out of pages, and initiate a print job.
22-4
Graphics Editor
Print Setup
Allows you to select a printer and printer connection. This command
presents a Print Setup dialog box where you specify the printer and its
connection.
Exit
Ends the graphics editor session. The graphics editor prompts you to save
documents with unsaved changes (ALT+F4).
22.2.4
Edit menu commands
The Edit menu offers the following commands:
Reverses the last editing action, if possible (CTRL+Z or
ALT+BACKSPACE). The name of the command changes depending on
what the last action was. The Undo command changes to Can’t Undo on the
menu if the last action cannot be reversed.
Cut
Removes the currently selected data from the document and put it on the
clipboard (CTRL+X). This command is unavailable if there is no data
currently selected. Cutting data to the clipboard replaces the contents
previously stored there.
Copy
Copies currently selected data onto the clipboard (CTRL+C). This command
is unavailable if there is no data currently selected. Copying data to the
clipboard replaces the contents previously stored there.
Paste
Inserts a copy of the clipboard contents at the insertion point (CTRL+V).
This command is unavailable if the clipboard is empty.
22.2.5
View menu commands
The View menu offers the following commands:
Toolbar
Displays and hides the Toolbar, which includes buttons for some of the most
common commands such as File Open. A check mark appears next to the
22-5
Graphics
Editor
Undo
GAUSS User Guide
menu item when the Toolbar is displayed. See T, Section ??, for help
on using the toolbar.
Status Bar
Displays and hides the Status Bar, which describes the action to be executed
by the selected menu or depressed toolbar button and keyboard latch state. A
check mark appears next to the menu item when the Status Bar is displayed.
See S B, Section ??, for help on using the status bar.
Properties
Allows you to change user-defined page/view settings. See S 
P/V P, Section 22.2.11, for more information.
Zoom
Allows you to change user-defined zoom control. See U  Z
F, Section 22.2.11, for more information.
22.2.6
Draw menu commands
The Draw menu offers the following commands; see G O, Section 22.2.13, for more
detailed information on each.
Select
Puts the editor into object selection state.
TKF Graphics
Opens a GAUSS graphics window.
Window
Line
Draws a line.
Arrow
Draws an arrow.
Rectangle
Draws a rectangle.
Ellipse
Draws an ellipse.
Text
Allows you to enter text.
22-6
Graphics Editor
22.2.7
Export menu commands
The Export menu offers the following commands; see F M, Section 22.3, for more
detailed information on each.
Encapsulated
Postscript
Writes an Encapsulated Postscript file.
JPEG Image
Writes a JPEG compressed image file.
Windows
Metafile
Writes a Windows Enhanced Metafile.
22.2.8
Help menu commands
Help Topics
Displays the opening screen of Help. From the opening screen, you can
jump to step-by-step instructions for using the graphics editor and various
types of reference information. Once you open Help, you can click the
Contents button whenever you want to return to the opening screen.
About
Displays the copyright notice and version number of this application.
22.2.9
Object Action Context Menu
Once an object has been selected, its action context menu may be displayed by right-clicking
inside the object.
The following actions may be selected from this menu:
Refresh
Redraws the object.
22-7
Graphics
Editor
The Help menu offers the following commands, which provide you assistance with this
application:
GAUSS User Guide
Cut
Removes the currently selected data from the document and put it on the
clipboard. This command is unavailable if there is no data currently selected.
Cutting data to the clipboard replaces the contents previously stored there.
Copy
Copies currently selected data onto the clipboard. This command is
unavailable if there is no data currently selected.
Delete
Deletes currently selected data. This command is unavailable if there is no
data currently selected.
Z-Order
Changes the objects position in the z-order of the document’s list. The
z-order allows the user to control in what order the object is drawn on the
page. To change, select the Z-Order menu item from the action context menu
and select one of the following:
Move to Top - Moves the object to the top of the list.
Move to Bottom - Moves the object to the bottom of the list.
Edit
Allows you to modify the object. This menu item currently applies to text
objects only.
Deselect
De-selects the object.
Properties
Opens the object’s property dialog.
22.2.10
Page Context Menu
The Page Context menu is displayed by pressing the right mouse button when no object is selected.
The following actions may be selected from this menu:
Paste
Copies an object from the clipboard to the page if one is available.
Retain Aspect
Check or uncheck the aspect ratio state. When checked, this forces the
object to retain its aspect ratio while sizing it from the top or sides; sizing
from the corners overrides this setting.
Ratio
See M  G O, Section 22.2.14, for more information.
22-8
Graphics Editor
22.2.11
Setting the Page/View Properties
The following describes how to set various page and view properties, including how to set the
page orientation and margins, use the zoom feature, and set the color options.
Setting the Page Orientation and Margins
The document page orientation of landscape or portrait is set from the
Properties dialog under the View menu.
Measure Units
Allows all coordinates and measurements to be in inches or centimeters.
Reference
Margin
A reference margin indicating the document’s current orientation and
margin settings is also available. This is useful for customizing your page to
be compatible with the printer currently in use. Because printer margins vary
from one printer to another, it is useful to be able to set your page to the
margins that most accurately match your printer.
The reference margin settings are available in the Properties dialog under the
View menu.
Reset Colors
Pushing this button will reset the available colors to the initial IBM 16-color
scheme. Each color may be set to a custom color; see P/F P,
Section 22.2.12 for more information.
Using the Zoom Feature
To set the zoom, click the zoom drop-down control on the toolbar or select Zoom in the View
menu.
Setting the Color Options
You may reset the colors to the original IBM 16-color scheme by pressing the Reset Colors to
Initial button.
22-9
Graphics
Editor
Page Orientation
GAUSS User Guide
22.2.12
Setting the Pen/Fill Properties
All drawing is done with a currently selected pen and brush. The current pen has a width attribute
and color attribute.
The current brush (for painting object backgrounds) has a color attribute.
Setting the Pen Color
Left-click in one of the color boxes in the dialog bar to set the current color. The dialog bar is
located to the left of the drawing area. The color is immediately displayed in the sample box at the
top of the color box area.
Double-clicking in the color box will allow you you to customize that particular color.
Setting the Pen Width
Left-click in one of the width boxes in the dialog bar shown below the color boxes.
Setting the Fill (brush) Color
Right-click in one of the color boxes in the dialog bar to set the current fill color. The dialog bar is
located to the left of the drawing area. The fill color is immediately displayed in the sample box at
the top of the color box area.
Transparent Fill
To set a transparent fill color, right-click in the sample box at the top of the
color boxes. This will cause the drawing object to have no fill associated
with it and allow objects beneath it to show through.
Customizing
the Color
Double-clicking in the color box will allow you to customize that particular
color.
22-10
Graphics Editor
22.2.13
Graphical Objects
The graphics editor allows the user to interactively create any number of the following graphical
objects for composing your document:
Creating a TKF Graphics window
A TKF Graphics Window is a window object containing a GAUSS-generated graphics file.
To create a TKF graphics window, select the Graphics Window menu item from the Draw menu or
press the Create TKF window icon on the toobar.
The graphics window border and fill colors may be set using their respective Color buttons.
Once the file has been selected and the user presses OK, the graphics window is created in a
default size located at the top-left corner of the page.
At this time, the window object may be modified.
Creating a Text Object
To create a text object, select the Text menu item from the Draw menu or press the Draw text
button on the toolbar.
Next, position the mouse where you want the top-left corner of your text then press and hold the
left mouse button. (You may also move the object by pressing and holding the right mouse button
while keeping the left button depressed). Drag the mouse to the bottom-left corner and let up on
the mouse button.
22-11
Graphics
Editor
A properties dialog is presented which allows the selection of a GAUSS-generated TKF graphics
file. There are two ways to do this. If one or more graphics files are currently being displayed in
GAUSS, those filenames will appear in the Active Graphs drop-down control and may be selected.
Otherwise, pressing the Browse button will present a common open file dialog for selecting the
file.
GAUSS User Guide
The text region will be redrawn in the current background fill color and contain a text cursor
inside. At this point you may enter your text at the cursor using the last selected text font.
If the text requires more lines than the current bounding box allows, the box will be resized as
needed.
To save your text when you have finished typing, press the OK icon on the text toolbar indicated
by a green check mark or press the SHIFT+ENTER key. Clicking the mouse button outside the
text window will also save the text and complete the operation.
The box will be redrawn with the proper font background, border color and margin settings.
To cancel out of the text and lose changes, press the Cancel icon on the text toolbar indicated by a
red X or press the ESCAPE key.
Note: The text object may be rotated at any angle from the Object Properties menu.
Creating a Line
To create a line, select the Line menu item from the Draw menu or press the Draw line button on
the toolbar. This puts the editor into the draw line state indicated by a crosshair cursor.
Next, position the mouse where you want the first end point of the line then press and hold the left
mouse button. (You may also move the line by pressing and holding the right mouse button while
keeping the left button depressed). Drag the mouse to the location for the second end point and
release the mouse button.
Note: Pressing the CTRL key while defining a line or arrow forces the line to be vertical or
horizontal.
The line will be redrawn in the current pen color.
At any time after the above process you may modify the line object.
22-12
Graphics Editor
Creating an Arrow
To create an arrow, select the Arrow menu item from the Draw menu or press the Draw arrow
button on the toolbar. This puts the editor into the draw arrow state indicated by a crosshair cursor.
Arrow style controls for defining the arrow appear on the dialog bar to the left of the drawing area.
Defining the endpoints are identical to the steps for defining a line above. However, the arrow head
size and shape may be set using the additional arrow style controls in the dialog bar.
Once the second endpoint is defined, the arrow will be redrawn in the current pen color.
At any time after the above process you may modify the arrow object.
Arrow Styles
There are a combination of two styles of arrows: Open/Closed, and Single/Double-headed arrows.
A single-headed arrow is a line with an arrowhead on one end. A double-headed arrow has an
arrowhead at both ends.
Creating a Rectangle
To create a rectangle object, select the Rectangle menu item from the Draw menu or press the
Draw rectangle button on the toolbar. This puts the editor into the draw rectangle state indicated
by a crosshair cursor.
Next, position the mouse where you want the top-left corner then press and hold the left mouse
button. (You may also move the object by pressing and holding the right mouse button while
keeping the left button depressed). Drag the mouse to the bottom-left corner and release the mouse
button.
The rectangle will be redrawn in the current background fill and border color.
22-13
Graphics
Editor
A closed arrow is one whose arrowhead is filled in with the current pen color. An open one has no
fill.
GAUSS User Guide
At any time after the above process you may modify the rectangle object.
Creating an Ellipse
Note: a circle is first created when defining an ellipse. After the circle has been defined it may be
dynamically reshaped into an ellipse of the desired size using the mouse.
To create the circle, select the Ellipse menu item from the Draw menu or press the Draw ellipse
button on the toolbar. This puts the editor into the draw ellipse state indicated by a crosshair cursor.
Next, position the mouse where you want the center of the circle then press and hold the left
mouse button. (You may also move the object by pressing and holding the right mouse button
while keeping the left button depressed). Drag the mouse to the desired radius and release the
mouse button.
The circle will be redrawn in the current background fill and border color.
At any time after the above process you may modify the circle to any other elliptical size and
shape.
22.2.14
Modifying the Graphical Objects
First, ensure you are in selection mode by pressing the Select toolbar button or choosing the Select
item in the Draw menu. Selection mode is indicated with an arrow cursor.
Next, select the object you want to modify by left-clicking anywhere inside or on the object. It
will then become highlighted.
Once selected, it may be sized, moved, or modified with one of the actions listed in the object’s
action context menu.
22-14
Graphics Editor
Aspect Ratio
You can force an object’s aspect ratio to be retained while sizing it by checking this menu item
from the Page Context menu.
When this is checked, all the sides of the object are sized by the same amount as the side being
moved, eliminating the need to resize all sides independently.
If the object is being sized by a corner point, this feature is ignored, eliminating the need for the
user to check/uncheck the aspect ratio menu item needlessly.
The aspect ratio feature has no effect for lines and arrows.
Object Properties
See G O, Section 22.2.13, for more information about object properties.
Sizing an Object
First select the object.
Next, click and hold the left mouse button in one of the object’s highlight points. Depending on
the type of object, the new size is defined by how you move the mouse. Lifting the mouse button
sets the new size and causes it to be redrawn.
If the object is a TKF graphics window, text object, rectangle, or ellipse, then the aspect ratio may
be retained depending on the selection state of the aspect ratio menu item state when grabbing one
of the four sides.
Grabbing the corner of an object allows you to size it in any direction ignoring the state of the
aspect ratio menu.
22-15
Graphics
Editor
The properties dialog box allows you to modify various attributes of the object depending on its
type.
GAUSS User Guide
If the object is a line or arrow, then it may be moved during the sizing operation by pressing and
holding the right mouse button while still depressing the left mouse button.
Note: A rotated text object may not be sized. It may only be sized in a non-rotated state.
Moving an Object
First select the object.
Next, click and hold the left mouse button somewhere inside the object. Drag the object to the new
location and lift the mouse button. The object is then redrawn in the new location.
If the object is a line or arrow, then it may also be moved during the sizing operation.
22.3
File Management
The graphics editor stores the document as a list of vector-based graphical objects. These are
binary files and cannot be edited by hand. It uses a default extension of .pge.
See the F   for available file operations.
You may export your document to other formats for inclusion in web pages, word-processors, and
publishing applications.
22.3.1
Exporting Files
The Export menu enables you to easily export graphic files to some of the most frequently used
graphic formats.
22-16
Graphics Editor
Writing an Encapsulated Postscript Image
To write an Encapsulated Postscript file, select the Encapsulated Postscript menu item from the
Export menu. This displays the entire file dialog.
Filename
Enter or browse to the desired output filename. The default extension is
.eps.
Convert lines
to Black
Check this item if you want to convert all colors in the image to black.
Scale Factor
Enter a scale factor if necessary. By default, the graphics editor uses a very
high internal resolution for the best possible quality. However, some
applications are unable to correctly scale the data when importing. This may
be worked around by scaling the data during the export stage.
Minimum line
width
Enter the minimum line width value if you want to darken the lines in
the exported file.
Graphics
Editor
Note About Fonts
Although the fonts you select for your text box may appear fine in the graphics editor, it is possible
the target application importing it may not interpret them correctly. Every application has its own
EPS interpreter, and the availability of your font depends on it. If you are having problems of this
type, try using the Enhanced Metafile format conversion. This format has no such font limitations.
Writing a JPEG Image
A JPEG image file is a widely used bitmap format for inclusion in web pages due to its
compression characteristics.
To write a JPEG file, select the JPEG Image File menu item from the Export menu.
Note: Because JPEG is a bitmap format, the image written to the file is exactly as seen on the
display. Thus you may be requried to zoom out on some lower-resolution displays to obtain an
image of the entire document.
22-17
GAUSS User Guide
Writing a TIFF Image
A TIFF (Tag Image File Format) image file is an older but widely used bitmap format.
To write a TIFF file, select the TIFF Image File menu item from the Export menu.
Note: Because TIFF is a bitmap format, the image written to the file is exactly as seen on the
display. Thus you may be required to zoom out on some lower-resolution displays to obtain an
image of the entire document.
Windows Metafile
An enhanced metafile is a vector-based file and is considered the best method for export/import on
the Microsoft Windows platform.
To create a Windows Enhanced Metafile, select the Windows Metafile menu item from the Export
menu.
Autoscale
Checking this option forces the translated to automatically scale the Enhanced Metafile. This is
the best setting for most applications for importing. However, some applications require a more
precise format. If the importing application has trouble, uncheck this option.
22-18
Time and Date
23
GAUSS offers a comprehensive set of time and date functions. These functions afford the user the
ability to return the current time and date, to carry out most related calculations and format the
results for output. GAUSS also allows the user to perform timed iterations.
dtvnormal and utctodtv are accurate back to 1 AD. The rest of the GAUSS date functions
assume a normal Gregorian system regardless of year. Thus, they will not account for the days
taken out in September of 1752, nor will they account for all century marks being leap years
before the adoption of the Gregorian system in 1752.
The time is given by your operating system, daylight savings time is not automatically accounted
for by GAUSS in calculations.
23-1
Time and Date
In the year 1 AD the calendar in general use was the Julian calendar. The Gregorian calendar that
we use today was not invented until the late 1500’s. This new calendar changed the method of
calculating leap years on century marks. With the Julian system simply every fourth year was a
leap year. The Gregorian system made every fourth year a leap year with the exception of century
marks which are only leap years if divisible by 400. The British adoption of this calendar, which
the GAUSS date functions are based on, did not happen until the year 1752. In that year eleven
days were removed; September 2, 1752 was followed by September 14, 1752.
GAUSS User Guide
23.1
Time and Date Formats
The Time and Date formats in GAUSS fall into one of two major categories, matrix/vector and
string. The matrix/vector formats can be used for either calculations or if desired for output. The
string formats are, however, mostly for use as ouput. Some manipulation of strings is possible
with the use of the stof function.
A 4×1 vector is returned by both the date and time functions.
d = date;
d;
1997.00
5.00000
29.0000
56.4700
/*
/*
/*
/*
Year */
Month */
Day */
Hundredths of a second since midnight */
t = time;
t;
10.00
17.00
33.00
13.81
/*
/*
/*
/*
Hours since midnight */
Minutes */
Seconds */
Hundredths of a second */
These vectors can be written to a string of the desired form by passing them through the
corresponding function.
d = { 1997, 5, 29, 56.47 };
datestr(d);
5/29/97
datestrymd(d);
23-2
Time and Date
19970529
t = { 10, 17, 33, 13.81 };
timestr(t);
10:17:33
A list and brief description of these, and other related functions is provided in the table in section
23.2.
Another major matrix/vector format is the dtv, or date and time vector. The dtv vector is a 1×8
vector used with the dtvnormal and utctodtv functions. The format for the dtv vector is:
Year Month Day Hour Min S ec DoW DiY
1955 4
21
4
16
0
4
110
Where:
Year, four digit integer.
1-12, Month in year.
1-31, Day of month.
0-23, Hours since midnight.
0-59, Minutes.
0-59, Seconds.
0-6, Day of week, 0=Sunday.
0-365, Days since Jan 1 of current year.
Time and Date
Year
Month
Day
Hour
Min
Sec
DoW
DiY
dtvnormal normalizes a date. The last two elements are ignored for input, as shown in the
following example. They are set to the correct values on output. The input can be 1×8 or N×8.
dtv = { 1954 3 17 4 16 0 0 0 };
dtv = dtvnormal(dtv);
23-3
GAUSS User Guide
1954 3 17 4 16 0 3 75
dtv[3] = dtv[3] + 400;
print dtv;
1954 3 417 4 16 0 3 75
dtv = dtvnormal(dtv);
print dtv;
1955 4 21 4 16 0 4 110
23.2
Time and Date Functions
Following is a partial listing of the time and date functions available in GAUSS.
23-4
datestr
Formats a Date vector to a string (mo/dy/yr).
datestrymd
Formats a Date vector to an eight character string of the type
yyyymmdd.
dayinyr
Returns day number in the year of a given date.
_daypryr
Returns the number of days in the years given as input.
dtvnormal
Normalizes a 1×8 dtv vector.
etdays
Computes the difference in days between two dates.
ethsec
Computes the difference between two times in hundredths of a
second.
etstr
Formats a time difference measured in hundreths of a second to a
string.
Time and Date
_isleap
Returns a vector of ones and zeros, 1 if leap year 0 if not.
timestr
Formats a Time vector to a string hr:mn:sc.
timeutc
Universal time coordinate, number of seconds since January 1, 1970
Greenwich Mean Time.
utctodtv
Converts a scalar, number of seconds since, or before, Jan 1 1970
Greenwich mean time, to a dtv vector.
Below is an example of two ways to calculate a time difference.
d1 = { 1996, 12, 19, 82 };
d2 = { 1997, 4, 28, 4248879.3 };
dif = ethsec(d1,d2);
ds = etstr(dif);
di f = 1.1274488e + 09
ds = 130days 11hours 48minutes 7.97seconds
Time and Date
If only the number of days is needed use etdays.
d1 = { 1996, 12, 19, 82 };
d2 = { 1997, 4, 28, 4248879.3 };
dif = etdays(d1,d2);
di f = 130.00000
The last element of d1 is optional when used as an input for etdays.
_isleap returns a matrix of ones and zeros, ones when the corresponding year is a leap year.
23-5
GAUSS User Guide
x = seqa(1970,1,20);
y = _isleap(x);
delif(x,abs(y-1));
1972.0000
1976.0000
1980.0000
1984.0000
1988.0000
/* Vector containing all leap years
between 1970 - 1989 */
To calculate the days of a number of consecutive years:
x = seqa(1983,1,3);
y = _daypryr(x);
sumc(y);
1096.0000
To add a portion of the following year:
g = { 1986, 2, 23, 0 };
dy = dayinyr(g);
sumc(y)+dy;
1150.0000
For more information on any of these functions see their respective pages in the command
reference.
23.2.1
Timed Iterations
Iterations of a program can be timed with the use of the hsec function in the following manner.
23-6
Time and Date
et = hsec;
/* Start timer */
/* Segment of code to be timed */
et = (hsec-et)/100;
/* Stop timer, convert to seconds */
In the case of a program running from one day into the next you would need to replace the hsec
function with the date function. The ethsec function should be used to compute the time
difference; a straight subtraction as in the previous example will not give the desired result.
dstart = date;
/* Start timer */
/* Segment of code to be timed */
dend = date;
/* Stop timer */
dif = ethsec(dstart,dend)/100;
/* Convert time difference to seconds */
Time and Date
23-7
ATOG
24
ATOG is a stand-alone conversion utility that converts ASCII files into GAUSS data sets. ATOG
can convert delimited and packed ASCII files into GAUSS data sets. ATOG can be run from a
batch file or the command line; it is not run from a GAUSS prompt but rather from a command
prompt window.
The syntax is:
atog cmdfile
24.1
Command Summary
The following commands are supported in ATOG:
24-1
ATOG
where cmdfile is the name of the command file. If no extension is given, .cmd will be assumed. If
no command file is specified, a command summary will be displayed.
GAUSS User Guide
append
Append data to an existing file.
complex
Treat data as complex variables.
input
The name of the ASCII input file.
invar
Input file variables (column names).
msym
Specify missing value character.
nocheck
Don’t check data type or record length.
output
The name of the GAUSS data set to be created.
outtyp
Output data type.
outvar
List of variables to be included in output file.
preservecase
Preserve case of variable names in output file.
The principle commands for converting an ASCII file that is delimited with spaces or commas are
given in the following example:
input agex.asc;
output agex;
invar $ race # age pay $ sex region;
outvar region age sex pay;
outtyp d;
In this example, a delimited ASCII file agex.asc is converted to a double precision GAUSS data
file agex.dat. The input file has five variables. The file will be interpreted as having five columns:
column
1
2
3
4
5
24-2
name
race
AGE
PAY
sex
region
data type
character
numeric
numeric
character
character
ATOG
The output file will have four columns since the first column of the input file (race) is not included
in the output variables. The columns of the output file are:
column
1
2
3
4
name
region
AGE
sex
PAY
data type
character
numeric
character
numeric
The variable names are saved in the file header. Unless preservecase has been specified, the
names of character variables will be saved in lowercase, and the names of numeric variables will
be saved in uppercase. The $ in the invar statement specifies that the variables that follow are
character type. The # specifies numeric. If $ and # are not used in an invar statement, the default
is numeric.
Comments in command files must be enclosed between ‘@’ characters.
24.2
Commands
A detailed explanation of each command follows.
append
Instructs ATOG to append the converted data to an existing data set:
ATOG
append;
No assumptions are made regarding the format of the existing file. Make certain that the number,
order, and type of data converted match the existing file. ATOG creates v96 format data files, so
will only append to v96 format data files.
24-3
GAUSS User Guide
complex
Instructs ATOG to convert the ASCII file into a complex GAUSS data set:
complex;
Complex GAUSS data sets are stored by rows, with the real and imaginary parts interleaved,
element by element. ATOG assumes the same structure for the ASCII input file, and will thus read
TWO numbers out for EACH variable specified.
complex cannot be used with packed ASCII files.
input
Specifies the file name of the ASCII file to be converted. The full path name can be used in the file
specification.
For example, the command:
input data.raw;
will expect an ASCII data file in the current working directory.
The command:
input /research/data/myfile.asc;
specifies a file to be located in the /research/data subdirectory.
24-4
ATOG
invar
Soft Delimited ASCII Files Soft delimited files may have spaces, commas, or cr/lf as delimiters
between elements. Two or more consecutive delimiters with no data between them are treated as
one delimiter. For example:
invar age $ name sex # pay var[1:10] x[005];
The invar command above specifies the following variables:
name
AGE
name
sex
PAY
VAR01
VAR02
VAR03
VAR04
VAR05
VAR06
VAR07
VAR08
VAR09
VAR10
X001
X002
X003
X004
X005
data type
numeric
character
character
numeric
numeric
numeric
numeric
numeric
numeric
numeric
numeric
numeric
numeric
numeric
numeric
numeric
numeric
numeric
numeric
ATOG
column
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
As the input file is translated, the first 19 elements will be interpreted as the first row (observation),
the next 19 will be interpreted as the second row, and so on. If the number of elements in the file is
not evenly divisible by 19, the final incomplete row will be dropped and a warning message will
be given.
24-5
GAUSS User Guide
Hard Delimited ASCII Files Hard delimited files have a printable character as a delimiter
between elements. Two delimiters without intervening data between them will be interpreted as a
missing. If \n is specified as a delimiter, the file should have one element per line and blank lines
will be considered missings. Otherwise, delimiters must be printable characters. The dot ‘.’ is
illegal and will always be interpreted as a missing value. To specify the backslash as a delimiter,
use \\. If \r is specified as a delimiter, the file will be assumed to contain one case or record per
line with commas between elements and no comma at the end of the line.
For hard delimited files the delimit subcommand is used with the invar command. The
delimit subcommand has two optional parameters. The first parameter is the delimiter. The
default is a comma. The second parameter is an ‘N’. If the second parameter is present, ATOG
will expect N delimiters. If it is not present, ATOG will expect N-1 delimiters.
This example:
invar delimit(, N) $ name # var[5];
will expect a file like this:
BILL ,
STEVE,
TOM ,
222.3,
624.3,
244.2,
123.2,
340.3,
834.3,
456.4,
,
602.3,
345.2,
624.3,
333.4,
while
invar delimit(,) $ name # var[5];
or
invar delimit $ name # var[5];
will expect a file like this:
24-6
533.2,
639.5,
822.5,
ATOG
BILL ,
STEVE,
TOM ,
222.3,
624.3,
244.2,
123.2,
340.3,
834.3,
456.4,
,
602.3,
345.2,
624.3,
333.4,
533.2,
639.5,
822.5
The difference between specifying N or N-1 delimiters can be seen here:
456.4,
,
602.3,
345.2,
624.3,
333.4,
533.2,
639.5,
If the invar statement specified three variables and N-1 delimiters, this file would be interpreted
as having three rows containing a missing in the [2,1] element and the [3,3] element like this:
456.4 345.2 533.2
.
624.3 639.5
602.3 333.4
.
If N delimiters had been specified, this file would be interpreted as having two rows, and a final
incomplete row that is dropped:
456.4 345.2 533.2
.
624.3 639.5
The spaces were shown only for clarity and are not significant in delimited files so:
ATOG
BILL,222.3,123.2,456.4,345.2,533.2,
STEVE,624.3,340.3,,624.3,639.5,
TOM,244.2,834.3,602.3,333.4,822.5
would work just as well.
Linefeeds are significant only if \n is specified as the delimiter, or when using \r. This example:
24-7
GAUSS User Guide
invar delimit(\r) $ name # var[5];
will expect a file with no comma after the final element in each row:
BILL ,
STEVE,
TOM ,
222.3,
624.3,
244.2,
123.2,
340.3,
834.3,
456.4,
245.3,
602.3,
345.2,
624.3,
333.4,
533.2
639.5
822.5
Packed ASCII Files Packed ASCII files must have fixed length records. The record
subcommand is used to specify the record length, and variables are specified by giving their type,
starting position, length, and the position of an implicit decimal point if necessary.
outvar is not used with packed ASCII files. Instead, invar is used to specify only those variables
to be included in the output file.
For packed ASCII files the syntax of the invar command is as follows:
invar record = reclen (format) variables (format) variables;
where,
reclen
the total record length in bytes, including the final carriage return/line feed if
applicable. Records must be fixed length.
format
(start,length.prec) where:
24-8
start
starting position of the field in the record, 1 is the first position. The default
is 1.
length
the length of the field in bytes. The default is 8.
prec
optional; a decimal point will be inserted automatically prec places in from
the RIGHT edge of the field.
ATOG
If several variables are listed after a format definition, each succeeding field will be assumed to
start immediately after the preceding field. If an asterisk is used to specify the starting position, the
current logical default will be assumed. An asterisk in the length position will select the current
default for both length and prec. This is illegal: (3,8.*).
The type change characters $ and # are used to toggle between character and numeric data type.
Any data in the record that is not defined in a format is ignored.
The examples below assume a 32-byte record with a carriage return/line feed occupying the last 2
bytes of each record. The data below can be interpreted in different ways using different invar
statements:
ABCDEFGHIJ12345678901234567890<CR><LF>
|
|
|
| |
|
position 1
10
20
30 31 32
This example:
invar record=32 $(1,3) group dept #(11,4.2) x[3] (*,5) y;
will result in:
value
ABC
DEF
12.34
56.78
90.12
34567
type
character
character
numeric
numeric
numeric
numeric
ATOG
variable
group
dept
X1
X2
X3
Y
This example:
invar record=32 $ dept (*,2) id # (*,5) wage (*,2) area
24-9
GAUSS User Guide
will result in:
variable
dept
id
WAGE
AREA
value
ABCDEFGH
IJ
12345
67
type
character
character
numeric
numeric
msym
Specifies the character in the input file that is to be interpreted as a missing value. This example:
msym &;
defines the character ‘&’ as the missing value character. The default ‘.’ (dot) will always be
interpreted as a missing value unless it is part of a numeric value.
nocheck
Optional; suppresses automatic checking of packed ASCII record length and output data type. The
default is to increase the record length by 2 bytes if the second record in a packed file starts with
cr/lf, and any files that have explicitly defined character data will be output in double precision
regardless of the type specified.
output
The name of the GAUSS data set. A file will be created with the extension .dat. For example:
output /gauss/dat/test;
creates the file test.dat on the /gauss/dat directory.
24-10
ATOG
outtyp
Selects the numerical accuracy of the output file. Use of this command should be dictated by the
accuracy of the input data and storage space limitations. The format is:
outtyp fmt;
where fmt is:
D or 8
F or 4
I or 2
double precision
single precision (default)
integer
The ranges of the different formats are:
bytes
data type
significant
digits
2
4
8
integer
single precision
double precision
4
6–7
15–16
range
−32768<=X<=32767
8.43x10−37 <=|X|<=3.37x10+38
4.19x10−307 <=|X|<=1.67x10+308
If the output type is integer, the input numbers will be truncated to integers. If your data has more
than 6 or 7 significant digits, specify outtyp as double.
Character data require outtyp d. ATOG automatically selects double precision when character
data is specified in the invar statement, unless you have specified nocheck.
The precision of the storage selected does not affect the accuracy of GAUSS calculations using the
data. GAUSS converts all data to double precision when the file is read.
ATOG
outvar
Selects the variables to be placed in the GAUSS data set. The outvar command needs only the
list of variables to be included in the output data set. They can be in any order. In this example:
24-11
GAUSS User Guide
invar $name #age pay $sex #var[1:10] x[005];
outvar sex age x001 x003 var[1:8];
the outvar statement selects the following variables:
column
1
2
3
4
5
6
7
8
9
10
11
12
name
sex
AGE
X001
X003
VAR01
VAR02
VAR03
VAR04
VAR05
VAR06
VAR07
VAR08
data type
character
numeric
numeric
numeric
numeric
numeric
numeric
numeric
numeric
numeric
numeric
numeric
outvar is not used with packed ASCII files.
preservecase
Optional; preserves the case of variable names. The default is nopreservcase, which will force
variable names for numeric variables to upper case and character variables to lower case.
24.3
Examples
Example 1 The first example is a soft delimited ASCII file called agex1.asc. The file contains
seven columns of ASCII data:
24-12
ATOG
Jan 167.3 822.4 6.34E06 yes 84.3 100.4
Feb 165.8 987.3 5.63E06 no 22.4 65.6
Mar 165.3 842.3 7.34E06 yes 65.4 78.3
The ATOG command file is agex1.cmd:
input /gauss/agex1.asc;
output agex1;
invar $month #temp pres vol $true var[02];
outvar month true temp pres vol;
The output data set will contain the following information:
name
case 1
case 2
case 3
type
month
Jan
Feb
Mar
char
true
yes
no
yes
char
TEMP
167.3
165.8
165.3
numeric
PRES
822.4
987.3
842.3
numeric
VOL
6.34e+6
5.63e+6
7.34e+6
numeric
The data set is double precision since character data is explicitly specified.
Example 2 The second example is a packed ASCII file xlod.asc The file contains 32-character
records:
ATOG
AEGDRFCSTy02345678960631567890<CR><LF>
EDJTAJPSTn12395863998064839561<CR><LF>
GWDNADMSTy19827845659725234451<CR><LF>
|
|
|
| |
|
position 1
10
20
30 31 32
The ATOG command file is xlod.cmd:
24-13
GAUSS User Guide
input /gauss/dat/xlod.asc;
output xlod2;
invar record=32 $(1,3) client[2] zone (*,1) reg #(20,5) zip;
The output data set will contain the following information:
name
case 1
case 2
case 3
type
client1
AEG
EDJ
GWD
char
client2
DRF
TAJ
NAD
char
zone
CST
PST
MST
char
reg
y
n
y
char
ZIP
60631
98064
59725
numeric
The data set is double precision since character data is explicitly specified.
Example 3 The third example is a hard delimited ASCII file called cplx.asc. The file contains
six columns of ASCII data:
456.4, 345.2,
-257.6, 624.3,
602.3, -333.4,
533.2, -345.5, 524.5, 935.3,
639.5, 826.5, 331.4, 376.4,
342.1, 816.7, -452.6, -690.8
The ATOG command file is cplx.cmd:
input /gauss/cplx.asc;
output cplx;
invar delimit #cvar[3];
complex;
The output data set will contain the following information:
name
case 1
case 2
case 3
type
24-14
cvar1
456.4 + 345.2i
-257.6 + 624.3i
602.3 - 333.4i
numeric
cvar2
533.2 - 345.5i
639.5 + 826.5i
342.1 + 816.7i
numeric
cvar3
524.5 + 935.3i
331.4 + 376.4i
-452.6 - 690.8i
numeric
ATOG
The data set defaults to single precision, since no character data is present, and no outtyp
command is specified.
24.4
Error Messages
atog - Can’t find input file
The ASCII input file could not be opened.
atog - Can’t open output file
The output file could not be opened.
atog - Can’t open temporary file
Notify Aptech Systems.
atog - Can’t read temporary file
Notify Aptech Systems.
atog - Character data in output file
Setting output file to double precision
The output file contains character data. The type was set to double precision
automatically.
atog - Character data longer than 8 bytes were truncated
ATOG
The input file contained character elements longer than 8 bytes. The conversion
continued and the character elements were truncated to 8 bytes.
atog - Disk Full
The output disk is full. The output file is incomplete.
atog - Found character data in numeric field
24-15
GAUSS User Guide
This is a warning that character data was found in a variable that was specified as
numeric. The conversion will continue.
atog - Illegal command
An unrecognizable command was found in a command file.
atog - Internal error
Notify Aptech Systems.
atog - Invalid delimiter
The delimiter following the backslash is not supported.
atog - Invalid output type
Output type must be I, F, or D.
atog - Missing value symbol not found
No missing value was specified in an msym statement.
atog - No Input file
No ASCII input file was specified. The input command may be missing.
atog - No input variables
No input variable names were specified. The invar statement may be missing.
atog - No output file
No output file was specified. The output command may be missing.
atog - output type d required for character data
Character data in output file will be lost
Output file contains character data and is not double precision.
24-16
ATOG
atog - Open comment
The command file has a comment that is not closed. Comments must be enclosed in @’s:
@ comment @
atog - Out of memory
Notify Aptech Systems.
atog - read error
A read error has occurred while converting a packed ASCII file.
atog - Record length must be 1-16384 bytes
The record subcommand has an out of range record length.
atog - Statement too long
Command file statements must be less than 16384 bytes.
atog - Syntax error at:
There is unrecognizable syntax in a command file.
atog - Too many input variables
More input variables were specified than available memory permitted.
atog - Too many output variables
ATOG
More output variables were specified than available memory permitted.
atog - Too many variables
More variables were specified than available memory permitted.
atog - Undefined variable
24-17
GAUSS User Guide
A variable requested in an outvar statement was not listed in an invar statement.
atog WARNING: missing ‘)’ at:
The parentheses in the delimit subcommand were not closed.
atog WARNING: some records begin with cr/lf
A packed ASCII file has some records that begin with a carriage return/linefeed. The
record length may be wrong.
atog - complex illegal for packed ASCII file.
A complex command was encountered following an invar command with record
specified.
atog - Cannot read packed ASCII. (complex specified)
An invar command with record specified was encountered following a complex
command.
24-18
Error
Messages
Error Messages
25
The following is a list of error messages intrinsic to the GAUSS programming language. Error
messages generated by library functions are not included here.
G0002 File too large
load
Input file too large.
getf
Input file too large.
G0003 Indexing a matrix as a vector
A single index can be used only on vectors. Vectors have only one row or only one
column.
G0004 Compiler stack overflow - too complex
An expression is too complex. Break it into smaller pieces. Notify Aptech Systems.
25-1
GAUSS User Guide
G0005 File is already compiled
G0006 Statement too long
Statement longer than 4000 characters.
G0007 End of file encountered
G0008 Syntax error
Compiler
Unrecognizable or incorrect syntax. Semicolon missing on previous
statement.
create
Unrecognizable statement in command file, or numvar or outvar
statement error.
G0009 Compiler pass out of memory
Compiler pass has run out of memory. Notify Aptech Systems.
G0010 Can’t open output file
G0011 Compiled file must have correct extension
GAUSS requires a .gcg extension.
G0012 Invalid drive specifier
G0013 Invalid filename
G0014 File not found
G0015 Directory full
G0016 Too many #include’s
#include’d files are nested too deep.
25-2
G0017 WARNING: local outside of procedure
A local statement has been found outside a procedure definition. The local statement
will be ignored.
G0018 Read error in program file
G0019 Can’t edit .gcg file
G0020 Not implemented yet
Command not supported in this implementation.
G0021 use must be at the beginning of a program
G0022 User keyword cannot be used in expression
G0023 Illegal attempt to redefine symbol to an index variable
G0024 Invalid use of ->, probably should be .
G0025 Undefined symbol
A symbol has been referenced that has not been given a definition.
G0026 Too many symbols
The global symbol table is full. (To set the limit, see new in the GAUSS L
R.)
G0027 Invalid directory
G0028 Can’t open configuration file
GAUSS cannot find the configuration file.
25-3
Error
Messages
Error Messages
GAUSS User Guide
G0029 Missing left parenthesis
G0030 Insufficient workspace memory
The space used to store and manipulate matrices and strings is not large enough for the
operations attempted. (To make the main program space smaller and reclaim enough
space to continue, see new in the GAUSS L R.)
G0031 Execution stack too deep - expression too complex
An expression is too complex. Break it into smaller pieces. Notify Aptech Systems.
G0032 fn function too large
G0033 Missing right index bracket
G0034 Missing arguments
G0035 Argument too large
G0036 Matrices are not conformable
For a description of the function or operator being used and conformability rules, see
M O, Section 7.2, or the GAUSS L R.
G0037 Result too large
The size of the result of an expression is greater than the limit for a single matrix.
G0038 Not all the eigenvalues can be computed
G0039 Matrix must be square to invert
G0040 Not all the singular values can be computed
25-4
G0041 Argument must be scalar
A matrix argument was passed to a function that requires a scalar.
G0042 Matrix must be square to compute determinant
G0043 Not implemented for complex matrices
G0044 Matrix must be real
G0045 Attempt to write complex data to real data set
Data sets, unlike matrices, cannot change from real to complex after they are created.
Use create complex to create a complex data set.
G0046 Columns don’t match
The matrices must have the same number of columns.
G0047 Rows don’t match
The matrices must have the same number of rows.
G0048 Matrix singular
The matrix is singular using the current tolerance.
G0049 Target matrix not complex
G0050 Out of memory for program
The main program area is full. (To increase the main program space, see new in the
GAUSS L R.)
G0051 Program too large
The main program area is full. (To increase the main program space, see new in the
GAUSS L R.)
25-5
Error
Messages
Error Messages
GAUSS User Guide
G0052 No square root - negative element
G0053 Illegal index
An illegal value has been passed in as a matrix index.
G0054 Index overflow
An illegal value has been passed in as a matrix index.
G0055 retp outside of procedure
A retp statement has been encountered outside a procedure definition.
G0056 Too many active locals
The execution stack is full. There are too many local variables active. Restructure your
program. Notify Aptech Systems.
G0057 Procedure stack overflow - expression too complex
The execution stack is full. There are too many nested levels of procedure calls.
Restructure your program. Notify Aptech Systems.
G0058 Index out of range
You have referenced a matrix element that is out of bounds for the matrix being
referenced.
G0059 exec command string too long
G0060 Nonscalar index
G0061 Cholesky downdate failed
G0062 Zero pivot encountered
crout
25-6
The Crout algorithm has encountered a diagonal element equal to 0.
Use croutp instead.
G0063 Operator missing
An expression contains two consecutive operands with no intervening operator.
G0064 Operand missing
An expression contains two consecutive operators with no intervening operand.
G0065 Division by zero!
G0066 Must be recompiled under current version
You are attempting to use compiled code from a previous version of GAUSS. Recompile
the source code under the current version.
G0068 Program compiled under GAUSS-386 real version
G0069 Program compiled under GAUSS-386i complex version
G0070 Procedure calls too deep
You may have a runaway recursive procedure.
G0071 Type mismatch
You are using an argument of the wrong data type (e.g., inputting a matrix when a string
is called for).
G0072 Too many files open
The limit on simultaneously open files is 10.
G0073 Redefinition of
declare
An attempt has been made to initialize a variable that is already
initialized. This is an error when declare := is used. declare !=
or declare ?= may be a better choice for your application.
25-7
Error
Messages
Error Messages
GAUSS User Guide
declare
An attempt has been made to redefine a string as a matrix or
procedure, or vice versa. delete the symbol and try again. If this
happens in the context of a single program, you have a programming
error. If this is a conflict between different programs, use a new
statement before running the second program.
let
A string is being forced to type matrix. Use an external matrix
symbol; statement before the let statement.
G0074 Can’t run program compiled under GAUSS Light
G0075 gscroll input vector the wrong size
G0076 Call Aptech Systems Technical Support
G0077 New size cannot be zero
You cannot reshape a matrix to a size of zero.
G0078 vargetl outside of procedure
G0079 varputl outside of procedure
G0080 File handle must be an integer
G0081 Error renaming file
G0082 Error reading file
G0083 Error creating temporary file
G0084 Too many locals
A procedure has too many local variables.
25-8
G0085 Invalid file type
You cannot use this kind of file in this way.
G0086 Error deleting file
G0087 Couldn’t open
The auxiliary output file could not be opened. Check the file name and make sure there
is room on the disk.
G0088 Not enough memory to convert the whole string
G0089 WARNING: duplicate definition of local
G0090 Label undefined
Label referenced has no definition.
G0091 Symbol too long
Symbols can be no longer than 32 characters.
G0092 Open comment
A comment was never closed.
G0093 Locate off screen
G0094 Argument out of range
G0095 Seed out of range
G0096 Error parsing string
parse encountered a token that was too long.
25-9
Error
Messages
Error Messages
GAUSS User Guide
G0097 String not closed
A string must have double quotes at both ends.
G0098 Invalid character for imaginary part of complex number
G0099 Illegal redefinition of user keyword
G0100 Internal E R R O R ###
Notify Aptech Systems.
G0101 Argument cannot be zero
The argument to ln or log cannot be zero.
G0102 Subroutine calls too deep
Too many levels of gosub. Restructure your program.
G0103 return without gosub
You have encountered a subroutine without executing a gosub.
G0104 Argument must be positive
G0105 Bad expression or missing arguments
Check the expression in question, or you forgot an argument.
G0106 Factorial overflow
G0107 Nesting too deep
Break the expression into smaller statements.
G0108 Missing left bracket [
25-10
G0109 Not enough data items
You omitted data in a let statement.
G0110 Found ) expected ] G0111 Found ] expected ) G0112 Matrix multiplication overflow
G0113 Unclosed (
G0114 Unclosed [
G0115 Illegal redefinition of function
You are attempting to turn a function into a matrix or string. If this is a name conflict,
delete the function.
G0116 sysstate:
invalid case
G0117 Invalid argument
G0118 Argument must be integer
File handles must be integral.
G0120 Illegal type for save
G0121 Matrix not positive definite
The matrix is either not positive definite, or singular using the current tolerance.
G0122 Bad file handle
The file handle does not refer to an open file or is not in the valid range for file handles.
25-11
Error
Messages
Error Messages
GAUSS User Guide
G0123 File handle not open
The file handle does not refer to an open file.
G0124 readr call too large
You are attempting to read too much in one call.
G0125 Read past end of file
You have already reached the end of the file.
G0126 Error closing file
G0127 File not open for write
G0128 File already open
G0129 File not open for read
G0130 No output variables specified
G0131 Can’t create file, too many variables
G0132 Can’t write, disk probably full
G0133 Function too long
G0134 Can’t seekr in this type of file
G0135 Can’t seek to negative row
G0136 Too many arguments or misplaced assignment operator
You have an assignment operator (=) where you want a comparison operator (= =), or
you have too many arguments.
25-12
G0137 Negative argument - erf or erfc
G0138 User keyword must have one argument
G0139 Negative parameter - Incomplete Beta
G0140 Invalid second parameter - Incomplete Beta
G0141 Invalid third parameter - Incomplete Beta
G0142 Nonpositive parameter - gamma
G0143 NaN or missing value - cdfchic
G0144 Negative parameter - cdfchic
G0145 Second parameter < 1.0 - cdfchic
G0146 Parameter too large - Incomplete Beta
G0147 Bad argument to trig function
G0148 Angle too large to trig function
G0149 Matrices not conformable
For a description of the function or operator being used and conformability rules, see
M O, Section 7.2, or the GAUSS L R.
G0150 Matrix not square
G0151 Sort failure
25-13
Error
Messages
Error Messages
GAUSS User Guide
G0152 Variable not initialized
You have referenced a variable that has not been initialized to any value.
G0153 Unsuccessful close on auxiliary output
The disk may be full.
G0154 Illegal redefinition of string
G0155 Nested procedure definition
A proc statement was encountered inside a procedure definition.
G0156 Illegal redefinition of procedure
You are attempting to turn a procedure into a matrix or string. If this is a name conflict,
delete the procedure.
G0157 Illegal redefinition of matrix
G0158 endp without proc
You are attempting to end a procedure that you never started.
G0159 Wrong number of parameters
You called a procedure with the wrong number of arguments.
G0160 Expected string variable
G0161 User keywords return nothing
G0162 Can’t save proc/keyword/fn with global references
Remove the global references or leave this in source code form for the autoloader to
handle. (See library in the GAUSS L R.)
25-14
G0163 Wrong size format matrix
G0164 Bad mask matrix
G0165 Type mismatch or missing arguments
G0166 Character element too long
The maximum length for character elements is 8 characters.
G0167 Argument must be column vector
G0168 Wrong number of returns
The procedure was defined to return a different number of items.
G0169 Invalid pointer
You are attempting to call a local procedure using an invalid procedure pointer.
G0170 Invalid use of ampersand
G0171 Called symbol is wrong type
You are attempting to call a local procedure using a pointer to something else.
G0172 Can’t resize temporary file
G0173 varindx failed during open
The global symbol table is full.
G0174 ‘‘.’’
and ‘‘ ’’ operators must be inside [ ] brackets
These operators are for indexing matrices.
25-15
Error
Messages
Error Messages
GAUSS User Guide
G0175 String too long to compare
G0176 Argument out of range
G0177 Invalid format string
G0178 Invalid mode for getf
G0179 Insufficient heap space
G0180 Trim too much
You are attempting to trim more rows than the matrix has.
G0181 Illegal assignment - type mismatch
G0182 2nd and 3rd arguments different order
G0274 Invalid parameter for conv
G0275 Parameter is NaN (Not A Number)
The argument is a NaN (see S D T, Section 6.6.9).
G0276 Illegal use of reserved word
G0277 Null string illegal here
G0278 proc without endp
You must terminate a procedure definition with an endp statement.
G0286 Multiple assign out of memory
G0287 Seed not updated
25-16
The seed argument to rndns and rndus must be a simple local or global variable
reference. It cannot be an expression or constant. These functions are obsolete, please
use rndlcn and rndlcu
G0288 Found break not in do loop
G0289 Found continue not in do loop
G0290 Library not found
The specified library cannot be found on the lib_path path. Make sure installation was
correct.
G0291 Compiler pass out of memory
Notify Aptech Systems.
G0292 File listed in library not found
A file listed in a library could not be opened.
G0293 Procedure has no definition
The procedure was not initialized. Define it.
G0294 Error opening temporary file
One of the temporary files could not be opened. The directory may be full.
G0295 Error writing temporary file
One of the temporary files could not be written to. The disk may be full.
G0296 Can’t raise negative number to nonintegral power
G0300 File handle must be a scalar
G0301 Syntax error in library
25-17
Error
Messages
Error Messages
GAUSS User Guide
G0302 File has been truncated or corrupted
getname
File header cannot be read.
load
Cannot read input file, or file header cannot be read.
open
File size does not match header specifications, or file header cannot
be read.
G0317 Can’t open temp file
G0336 Disk full
G0339 Can’t debug compiled program
G0341 File too big
G0347 Can’t allocate that many globals
G0351 Warning:
Not reinitializing :
declare ?=
The symbol is already initialized. It will be left as is.
G0352 Warning:
Reinitializing :
declare !=
The symbol is already initialized. It will be reset.
G0355 Wrong size line matrix
G0360 Write error
G0364 Paging error
G0365 Unsupported executable file type
25-18
G0368 Unable to allocate translation space
G0369 Unable to allocate buffer
G0370 Syntax Error in code statement
G0371 Syntax Error in recode statement
G0372 Token verify error
Notify Aptech Systems.
G0373 Procedure definition not allowed
A procedure name appears on the left side of an assignment operator.
G0374 Invalid make statement
G0375 make Variable is a Number
G0376 make Variable is Procedure
G0377 Cannot make Existing Variable
G0378 Cannot make External Variable
G0379 Cannot make String Constant
G0380 Invalid vector statement
G0381 vector Variable is a Number
G0382 vector Variable is Procedure
25-19
Error
Messages
Error Messages
GAUSS User Guide
G0383 Cannot vector Existing Variable
G0384 Cannot vector External Variable
G0385 Cannot vector String Constant
G0386 Invalid extern statement
G0387 Cannot extern number
G0388 Procedures always external
A procedure name has been declared in an extern statement. This is a warning only.
G0389 extern variable already local
A variable declared in an extern statement has already been assigned local status.
G0390 String constant cannot be external
G0391 Invalid code statement
G0392 code Variable is a Number
G0393 code Variable is Procedure
G0394 Cannot code Existing Variable
G0395 Cannot code External Variable
G0396 Cannot code String Constant
G0397 Invalid recode statement
25-20
G0398 recode Variable is a Number
G0399 recode Variable is Procedure
G0400 Cannot recode External Variable
G0401 Cannot recode String Constant
G0402 Invalid keep statement
G0403 Invalid drop statement
G0404 Cannot define Number
G0405 Cannot define String
G0406 Invalid select statement
G0407 Invalid delete statement
G0408 Invalid outtyp statement
G0409 outtyp already defaulted to 8
Character data has been found in the output data set before an outtyp 2 or outtyp 4
statement. This is a warning only.
G0410 outtyp must equal 2, 4, or 8
G0411 outtyp override...precision set to 8
Character data has been found in the output data set after an outtyp 2 or outtyp 4
statement. This is a warning only.
25-21
Error
Messages
Error Messages
GAUSS User Guide
G0412 default not allowed in recode statement
default allowed only in code statement.
G0413 Missing file name in dataloop statement
G0414 Invalid listwise statement
G0415 Invalid lag statement
G0416 lag variable is a number
G0417 lag variable is a procedure
G0418 Cannot lag External Variable
G0419 Cannot lag String Constant
G0421 Command not supported in Run-Time Module
G0428 Cannot use debug command inside program
G0429 Invalid number of subdiagonals
G0431 Error closing dynamic library
G0432 Error opening dynamic library
G0433 Cannot find DLL function
G0434 Error opening default dynamic library
G0435 Invalid mode
25-22
G0436 Matrix is empty
G0437 loadexe not supported; use dlibrary instead
G0438 callexe not supported; use dllcall instead
G0439 File has wrong bit order
G0440 File has wrong byte order
G0441 Type vector malloc failed
G0442 No type vector in gfblock
G0445 Illegal left-hand side reference in procedure
G0446 Argument is the wrong size
G0447 vfor called with illegal loop level
G0454 Failure opening printer for output
G0456 Failure buffering output for printer
G0457 Cannot take log of a negative number
G0458 Attempt to index proc/fn/keyword as a matrix
G0459 Missing right brace
G0460 Unexpected end of statement
25-23
Error
Messages
Error Messages
GAUSS User Guide
G0461 Too many data items
G0462 Negative trim value
G0463 Failure generating graph
G0465 Redefinition of structure, number of elements
G0466 Redefinition of structure, type mismatch
G0467 Redefinition of structure, unrecognized member
G0468 Structure definition inside procedure definition
G0469 Cannot create translator temp file
G0470 Symbol not found
G0472 Invalid name
G0473 String not terminated with null byte
G0477 FOR loops nested too deep
G0486 Character argument too long
G0487 License expired
G0490 License manager initialization error
G0491 License manager error
25-24
G0492 Licensing failure
G0497 Missing right parenthesis
G0500 Cannot create temporary filename
G0503 Cannot assign matrix to scalar member
G0504 Invalid structure member
G0505 Invalid structure redefinition
G0506 Structure assignment mismatch
G0507 Undefined structure
G0508 Structure argument mismatch
G0509 Too many structure members
G0510 Duplicate name for structure member
G0514 Not supported for structures
G0515 Too many values in locator
G0516 Too many dimensions in result
G0517 Too many dimensions in argument
G0518 Not implemented for complex
25-25
Error
Messages
Error Messages
GAUSS User Guide
G0519 Illegal dereference of structure array
G0520 Arguments not conformable
G0521 Argument must be real
G0522 Illegal indexing of dereferenced structure
G0523 Numeric argument must be integer
G0524 Found comma, expecting index
G0525 Argument contains NaNs
G0526 Argument must be compact format
G0529 Array orders must be >= 1
G0531 Two trailing dimensions of argument must be the same size
G0532 Both dimensions of argument must be the same size
G0533 1-dimensional argument must contain only 1 element
G0534 Cannot create file
G0538 Zero illegal in for loop increment
G0541 Illegal assignment to FOR loop counter
G0542 Object too large for 32-bit version
25-26
G0543 Array has too many dimensions for matrix assign
G0547 Array not conformable for indexing
G0548 Array not conformable for boolean operation
G0549 Global structure pointer cannot point to local structure
G0550 Invalid use of *
G0551 Feature not authorized
G0553 Path too long
G0554 Unable to create sparse matrix
G0555 Cannot index uninitialized structure
G0556 #IF nesting limit exceeded
G0557 #ELSE without #IF
G0558 #ENDIF without #IF
G0559 Symbol not #DEFINE’d
G0560 Too many #DEFINE’s
G0561 Duplicate #DEFINE
G0562 Open /* */ comment
25-27
Error
Messages
Error Messages
GAUSS User Guide
G0563 Open @ @ comment
G0564 Illegal redefinition of sparse matrix
G0565 Initializer too large, increase maxdeclet in config (.cfg) file
G0566 Can’t create profiler data file
G0567 Sparse matrix uninitialized
G0568 Operation not defined for triangular, symmetric, or Hermitian sparse
matrix
G0569 Argument must be complex
G0570 Diagonal must be real
G0571 Diagonal must not contain zeros
G0572 Argument must be triangular
G0573 Argument must be symmetric
G0574 Sparse type mismatch
G0575 Unable to load variable
G0576 Threading error
G0577 Expected THREADSTAT, THREADBEGIN, or THREADJOIN
25-28
G0578 A THREADJOIN failed
G0579 Cannot call RUN from inside thread
G0580 Unable to converge in allowed number of iterations
G0581 Incorrect Argument:
Number of eigenvalues must be positive
G0582 Incorrect Argument: Number of column vectors must be >= number of
eigenvalues +2 and < rows of input matrix
G0583 Could not apply shift during an Arnoldi iteration cycle.
increasing size of ncv
G0584 Invalid Input:
type string
Try
’which’ must be ’LM’ ’SM’ ’LR’ ’LI’ ’SR’ or ’SI’ and
G0585 Error Return from LAPACK eigenvalue calculation
G0586 dneupd error 1:
contact Aptech Systems
G0587 Input matrix must be sparse
G0588 Incorrect Input:
Number of eigenvalues must be scalar
G0589 Incorrect Input:
Tolerance must be scalar
G0590 No eigenvalues found to specified tolerance in allowed iterations
G0591 Incorrect Input:
Max iterations must be scalar
G0592 Incorrect Input:
Number of column vectors must be scalar
25-29
Error
Messages
Error Messages
GAUSS User Guide
G0593 Incorrect Input:
Third input, probability, must be > 0 and < 1
G0594 Incorrect Input: Number of successes (input 1) must be less than
number of trials (input 2)
G0595 Incorrect Input:
State vector cannot have more than 1 column
G0596 Incorrect Input:
1x1 matrix
Inputs 1 and 2 (cols and rows) must be scalar or
G0597 Incorrect Input:
Input must be dense matrix
G0598 Incorrect Input:
First input may have 1 column only
G0599 Incorrect Input:
rows
Input 2 may not have more columns that input 1 has
G0600 Incorrect Input:
Input 1 must be square
G0601 Incorrect Input:
Input 2 must be square
G0602 Incorrect Input:
1 <= il < iu and iu <= rows of x
G0603 Failure to converge
25-30
26
These hints will help you maximize the performance of your new GAUSS System.
26.1
Library System
Some temporary files are created during the autoloading process. If you have a tmp_path
configuration variable or a tmp environment string that defines a path on a RAM disk, the
temporary files will be placed on the RAM disk.
For example:
set tmp=f:\tmp
tmp_path takes precedence over the tmp environment variable.
A disk cache will also help, as well as having your frequently used files in the first path in the
src_path.
26-1
Performance
Maximizing Performance
GAUSS User Guide
You can optimize your library .lcg files by putting the correct drive and path on each file name
listed in the library. The lib command will do this for you.
Use the compile command to precompile your large frequently used programs. This will
completely eliminate compile time when the programs are rerun.
26.2
Loops
The use of the built-in matrix operators and functions rather than do loops will ensure that you are
utilizing the potential of GAUSS.
Here is an example:
Given the vector x with 8000 normal random numbers,
x = rndn(8000,1);
you could get a count of the elements with an absolute value greater than 1 with a do loop, like
this:
c = 0;
i = 1;
do while i <= rows(x);
if abs(x[i]) > 1;
c = c+1;
endif;
i = i+1;
endo;
print c;
Or, you could use:
26-2
Maximizing Performance
c = sumc(abs(x) .> 1);
print c;
26.3
Performance
The do loop takes over 40 times longer.
Memory Usage
Computers today can have large amounts of RAM. This doesn’t mean that large data sets should
be read entirely into memory. Many GAUSS procedures and applications are written to allow for
data sets to be read in sections rather than all at once. Even if you have enough RAM to store the
data set completely, you should consider taking advantage of this feature. The speed-ups using this
feature can be significant. For example, ols is called using a data set stored in a matrix versus
stored on the disk in a GAUSS data set. The computer is a 2.8 Megahertz computer with Windows
XP.
y = rndn(250000,1);
x = rndn(250000,100);
xlbl = 0$+"X"+ftocv(seqa(1,1,100),1,0);
lbl = "Y" | xlbl;
call saved(y˜x,"test",lbl);
__output = 0;
t0 = date;
call ols("",y,x);
t1 = date;
t2 = date;
call ols("test","Y",xlbl);
t3 = date;
print ethsec(t2,t3)/100 " seconds;
print;
print ethsec(t0,t1)/100 " seconds";
25.750000 seconds
9.6720000 seconds
26-3
GAUSS User Guide
This represents more than a 50% speedup by leaving the data on the disk.
maxvec,maxbytes
maxvec is a GAUSS procedure that returns the value of the global variable __maxvec that
determines the amount of data to be read in at a time from a GAUSS data set. This value can be
modified for a particular run by setting __maxvec in your command file to some other value. The
value returned by a call to maxvec can be permanently modified by editing system.dec and
changing the value of __maxvec. The value returned when running GAUSS Light is always 8192.
maxbytes is a GAUSS procedure that returns the value of a scalar global __maxbytes that sets
the amount of available RAM. This value can be modified for a particular run by setting
__maxbytes in your command file to some other value. The value returned by a call to maxbytes
can be permanently modified by editing system.dec and changing the value of __maxbytes.
If you wish to force GAUSS procedures and applications to read a GAUSS data set in its entirety,
set __maxvec and __maxbytes to very large values.
26.3.1
Hard Disk Maintenance
The hard disk used for the swap file should be optimized occasionally with a disk optimizer. Use a
disk maintenance program to ensure that the disk media is in good shape.
26.3.2
CPU Cache
There is a line for cache size in the gauss.cfg file. Set it to the size of the CPU data cache for
your computer.
This affects the choice of algorithms used for matrix multiply functions.
This will not change the results you get, but it can radically affect performance for large matrices.
26-4
Fonts
There are four fonts available in the Publication Quality Graphics System:
Simplex
Simgrma
Microb
complex
standard sans serif font
Simplex greek, math
bold and boxy
standard font with serif
The following tables show the characters available in each font and their ASCII values. (For
details on selecting fonts for your graph, see S F, Section 21.4.1.
A-1
Fonts
A
GAUSS User Guide
A.1
A-2
Simplex
Fonts
A.2
Simgrma
Fonts
A-3
GAUSS User Guide
A.3
A-4
Microb
Fonts
A.4
Complex
Fonts
A-5
Reserved Words Appendix
B
A
abs
acf
aconcat
acos
aeye
amax
amean
AmericanBinomCall
AmericanBinomCall_Greeks
AmericanBinomCall_ImpVol
AmericanBinomPut
AmericanBinomPut_Greeks
AmericanBinomPut_ImpVol
AmericanBSCall
AmericanBSCall_Greeks
AmericanBSCall_ImpVol
AmericanBSPut
AmericanBSPut_Greeks
AmericanBSPut_ImpVol
amin
amult
and
annualTradingDays
arccos
arcsin
arctan
B-1
Reserved
Words
The following words are used for GAUSS functions. You cannot use these names for variables or
procedures in your programs:
GAUSS User Guide
arctan2
areshape
arrayalloc
arrayindex
arrayinit
arraytomat
asclabel
asin
asum
atan
atan2
atranspose
axmargin
balance
band
bandchol
bandcholsol
bandltsol
bandrv
bandsolpd
bar
base10
begwind
besselj
bessely
box
boxcox
break
calcbox
call
callexe
cdfbeta
cdfbvn
cdfbvn2
cdfbvn2e
cdfchic
cdfchii
cdfchinc
cdffc
cdffnc
cdfgam
cdfmvn
cdfn
cdfn2
cdfnc
cdfni
cdftc
cdftci
cdftnc
cdftvn
cdir
ceil
cfft
cffti
changedir
chdir
B
C
B-2
Reserved Words Appendix
cons
continue
contour
conv
convertsatostr
convertstrtosa
coreleft
corrm
corrms
corrvc
corrx
corrxs
cos
cosh
counts
countwts
create
crossprd
crout
croutp
csrcol
csrlin
csrtype
cumprodc
cumsumc
curve
cvtos
cvtosa
datacreate
datacreatecomplex
datalist
dataload
dataopen
datasave
date
datestr
Reserved
Words
checkinterrupt
chol
choldn
cholsol
cholup
chrs
cint
clear
clearg
close
closeall
cls
cmsplit
cmsplit2
code
color
cols
colsf
combinate
combinated
comlog
commandeerm
commandeersa
compile
complex
con
cond
conformed
conj
D
B-3
GAUSS User Guide
datestring
datestrymd
dayinyr
dayOfWeek
debug
declare
delete
deletefile
delif
denseSubmat
design
det
detl
dfft
dffti
dfree
diag
diagrv
digamma
disable
dlibrary
dllcall
do
dos
doswincloseall
doswinopen
dotfeq
dotfeqmt
dotfge
dotfgemt
dotfgt
dotfgtmt
dotfle
dotflemt
dotflt
dotfltmt
dotfne
dotfnemt
draw
dsCreate
dstat
dstatmt
dstatmtControlCreate
dtdate
dtday
dttime
dttodtv
dttostr
dttoutc
dtvnormal
dtvtodt
dtvtoutc
dummy
dummybr
dummydn
ed
edit
editm
eig
eigcg
eigcg2
eigch
eigch2
eigh
eighv
E
B-4
Reserved Words Appendix
erfc
error
errorlog
etdays
ethsec
etstr
EuropeanBinomCall
EuropeanBinomCall_Greeks
EuropeanBinomCall_ImpVol
EuropeanBinomPut
EuropeanBinomPut_Greeks
EuropeanBinomPut_ImpVol
EuropeanBSCall
EuropeanBSCall_Greeks
EuropeanBSCall_ImpVol
EuropeanBSPut
EuropeanBSPut_Greeks
EuropeanBSPut_ImpVol
exctsmpl
exec
execbg
exp
expr
external
eye
fcheckerr
fclearerr
feq
feqmt
fflush
fft
ffti
fftm
fftmi
fftn
fge
fgemt
fgets
fgetsa
fgetsat
fgetst
Reserved
Words
eigrg
eigrg2
eigrs
eigrs2
eigv
elapsedTradingDays
else
elseif
enable
end
endfor
endif
endo
endp
endwind
envget
eof
eq
eqSolve
eqSolvemt
eqSolvemtControlCreate
eqSolvemtOutCreate
eqSolveSet
eqv
erf
F
B-5
GAUSS User Guide
fgt
fgtmt
fileinfo
files
filesa
fix
fle
flemt
floor
flt
fltmt
fmod
fn
fne
fnemt
font
fontload
fonts
fontunload
fontunloadall
fopen
for
format
formatcv
formatnv
fputs
fputst
fseek
fstrerror
ftell
ftocv
ftos
ftostrc
gamma
gammaii
gausset
gdaappend
gdacreate
gdadstat
gdadstatmat
gdagetindex
gdagetname
gdagetnames
gdagetorders
gdagettype
gdagettypes
gdagetvarinfo
gdaiscplx
gdapack
gdaread
gdareadbyindex
gdareadsome
gdareportvarinfo
gdaupdate
gdaupdateandpack
gdawrite
gdawritesome
gdtfastcat
ge
getarray
getdims
getf
getmatrix
getmatrix4d
getname
G
B-6
Reserved Words Appendix
getnamef
getNextTradingDay
getNextWeekDay
getnr
getnrmt
getorders
getpath
getPreviousTradingDay
getPreviousWeekDay
getscalar3d
getscalar4d
getwind
gosub
goto
gradMT
gradMTm
gradp
graph
graphgpg
graphinit
graphprt
graphset
graphsev3
gt
hardcopy
hasimag
header
headermt
hess
hessMT
hessMTg
hessMTgw
hessMTm
hessMTmw
hessMTw
hessp
hist
histf
histp
hsec
if
imag
indcv
indexcat
indices
indices2
indicesf
indicesfn
indnv
indsav
int
intgrat2
intgrat3
inthp
intHP1
intHP2
H
Reserved
Words
I
B-7
GAUSS User Guide
intHP3
intHP4
inthpControlCreate
intquad1
intquad2
intquad3
intrleav
intrleavsa
intrsect
intrsectsa
intsimp
inv
invpd
invswp
iscplx
iscplxf
isinfnanmiss
ismiss
isSparse
key
keyav
keymatchmc
keyw
keyword
lag
lag1
lagn
lapeighb
lapeighi
lapeighvb
lapeighvi
lapgeig
lapgeigh
lapgeighv
lapgeigv
lapgschur
lapgsvdcst
lapgsvds
lapgsvdst
lapsvdcusv
lapsvds
lapsvdusv
le
let
lib
library
license_id
line
linsolve
ln
lncdfbvn
lncdfbvn2
lncdfmvn
lncdfn
lncdfn2
lncdfnc
K
L
B-8
Reserved Words Appendix
loess
loessmt
loessmtControlCreate
log
loglog
logx
logy
loopnextindex
lower
lowmat
lowmat1
lpos
lprint
lpwidth
lshow
lt
ltrisol
lu
lusol
machEpsilon
makevars
makewind
margin
matalloc
matinit
matrix
mattoarray
maxbytes
maxc
maxindc
maxvec
mbesselei
mbesselei0
mbesselei1
mbesseli
mbesseli0
mbesseli1
meanc
median
mergeby
mergebysa
mergevar
minc
minindc
miss
missex
missrv
Reserved
Words
lnfact
lngamma
lnpdfmvn
lnpdfmvt
lnpdfn
lnpdft
load
loadarray
loadd
loadexe
loadf
loadk
loadm
loadp
loads
loadstruct
loadwind
local
locate
M
B-9
GAUSS User Guide
moment
momentd
movingave
movingaveExpwgt
movingaveWgt
msym
nametype
ndpchk
ndpclex
ndpcntrl
ne
new
nextindex
nextn
nextnevn
nextwind
not
null
null1
numCombinations
oldfft
oldffti
ols
olsmt
olsmtControlCreate
olsqr
olsqr2
olsqrmt
ones
open
openpqg
optn
optnevn
or
orth
output
outwidth
pacf
packr
parse
pause
pdfn
pi
pinv
pinvmt
plot
plotsym
N
O
P
B-10
Reserved Words Appendix
putarray
putf
pvCreate
pvgetindex
pvgetparnames
pvgetparvector
pvLength
pvList
pvnumoffsets
pvoffsets
pvPack
pvPacki
pvPackm
pvPackmi
pvPacks
pvPacksi
pvPacksm
pvPacksmi
pvputparvector
pvtest
pvunpack
QNewton
QNewtonmt
QNewtonmtControlCreate
QNewtonmtOutCreate
qnewtonset
QProg
QProgmt
qprogMTInCreate
qqr
qqre
qqrep
qr
qre
qrep
qrsol
qrtsol
qtyr
qtyre
qtyrep
quantile
quantiled
quantilem
quantilemd
qyr
Reserved
Words
polar
polychar
polyeval
polyint
polymake
polymat
polymroot
polymult
polyroot
pop
pqgwin
prcsn
previousindex
princomp
print
printdos
printfm
printfmt
proc
prodc
push
Q
B-11
GAUSS User Guide
qyre
qyrep
rank
rankindx
readr
real
recode
recserar
recsercp
recserrc
register_off
register_on
register_reset
register_show
renamefile
replay
rerun
reshape
retp
return
rev
rfft
rffti
rfftip
rfftn
rfftnp
rfftp
rndbeta
rndcon
rndgam
rndi
rndKMbeta
rndKMgam
rndkmi
rndkmn
rndKMnb
rndKMp
rndkmu
rndKMvm
rndLCbeta
rndLCgam
rndlci
rndlcn
rndLCnb
rndLCp
rndlcu
rndLCvm
rndmod
rndmult
rndn
rndnb
rndns
rndp
rndseed
rndu
rndus
rndvm
rotater
round
rows
rowsf
rref
run
R
B-12
Reserved Words Appendix
S
sinh
sleep
solpd
sortc
sortcc
sortd
sorthc
sorthcc
sortind
sortindc
sortindmc
sortmc
sortr
sortrc
sparseCols
sparseEye
sparseFD
sparseFP
sparseHConcat
sparseNZE
sparseOnes
sparseRows
sparseScale
sparseSet
sparseSolve
sparseSubmat
sparseTD
sparseTranspose
sparseTrTD
sparseTscalar
sparseVConcat
spline
spline1D
spline2D
sqpmt_feasible
Reserved
Words
satocv
satostrC
save
saveall
saved
savestruct
savewind
scale
scale3d
scalerr
scalinfnanmiss
scalmiss
schtoc
schur
screen
scroll
searchsourcepath
seekr
selif
seqa
seqm
setarray
setcnvrt
setdif
setdifsa
setvars
setvmode
setvwrmode
setwind
shell
shiftr
show
showpqg
sin
singleindex
B-13
GAUSS User Guide
sqpmt_meritFunct
sqpSolve
SQPsolveMT
sqpSolveMTcontrolCreate
sqpSolveMTlagrangeCreate
sqpSolveMToutCreate
sqpSolveset
sqrt
stdc
stocv
stof
stop
strcombine
strindx
string
strlen
strput
strrindx
strsect
strsplit
strsplitpad
strtodt
strtodtd
strtof
strtofcplx
strtriml
strtrimr
strtrunc
strtruncl
strtruncpad
strtruncr
struct
submat
subscat
substute
subvec
sumc
sumr
surface
svd
svd1
svd2
svdcusv
svds
svdusv
sysstate
system
tab
tan
tanh
tempname
ThreadBegin
ThreadEnd
ThreadJoin
ThreadStat
time
timedt
timestr
timeutc
title
tkf2eps
tkf2ps
tkf2ps_margin
tocart
todaydt
T
B-14
Reserved Words Appendix
toeplitz
token
topolar
trace
trap
trapchk
trigamma
trim
trimr
trunc
type
typecv
typef
union
unionsa
uniqindmc
uniqindx
uniqindxsa
unique
uniquemc
uniquesa
until
upmat
upmat1
upper
use
utctodt
utctodtv
utrisol
vals
varget
vargetl
varmall
varmares
varput
varputl
vartype
vartypef
vcm
vcms
vcx
vcxs
vec
vech
vecr
vfor
vget
view
viewxyz
vlist
vnamecv
volume
vput
vread
vtypecv
U
Reserved
Words
V
B-15
GAUSS User Guide
W
wait
waitc
walkindex
while
winclear
wincleararea
winclearttylog
winclose
wincloseall
winconvertpqg
window
wingetactive
wingetattributes
wingetcolorcells
wingetcursor
winmove
winopenpqg
winopentext
winopentty
winpan
winprint
winprintpqg
winrefresh
winrefresharea
winresize
winsetactive
winsetbackground
winsetcolor
winsetcolorcells
winsetcolormap
winsetcursor
winsetforeground
winsetrefresh
winsettextwrap
winwrite
winzoompqg
writer
x_indcv
xlabel
xor
xpnd
xtics
xy
xyz
ylabel
ytics
X
Y
B-16
Reserved Words Appendix
Z
zeros
zlabel
ztics
Reserved
Words
B-17
Singularity Tolerance Appendix
C
The tolerance used to determine whether or not a matrix is singular can be changed. The default
value is 1.0e-14 for both the LU and the Cholesky decompositions. The tolerance for each
decomposition can be changed separately. The following operators are affected by a change in the
tolerance:
crout(x)
croutp(x)
inv(x)
det(x)
y/x
Singularity
Crout LU Decomposition
when neither x nor y is scalar and x is square.
Cholesky Decomposition
chol(x)
invpd(x)
solpd(y,x)
y/x
when neither x nor y is scalar and x is not square.
C-1
GAUSS User Guide
C.1
Reading and Setting the Tolerance
The tolerance value may be read or set using the sysstate function, cases 13 and 14.
C.2
Determining Singularity
There is no perfect tolerance for determining singularity. The default is 1.0e-14. You can adjust
this as necessary.
A numerically better method of determining singularity is to use cond to determine the condition
number of the matrix. If the equation
1 / cond(x) + 1 eq 1
is true, then the matrix is usually considered singular to machine precision. (See LAPACK for a
detailed discussion on the relationship between the matrix condition and the number of significant
figures of accuracy to be expected in the result.)
C-2
Index
Index
0 , 7-8
.0 , 7-8
∼ , 7-9
| , 7-8
! , 7-6
*∼ , 7-7
∗ , 7-5
.* , 7-6
.*. , 7-6
+ , 7-4
− , 7-4
/ , 7-5
./ , 7-6
% , 7-5
ˆ , 7-6, 7-19
.ˆ , 7-6
,
.
:
;
(comma) , 7-16
(dot) , 7-16
(colon) , 7-17
(semicolon) , 6-2
/ = , 7-11
./= , 7-12
= = , 6-40, 7-10
.= = , 7-12
> , 7-11
. > , 7-12
>= , 7-11
. >= , 7-12
< , 7-10
. < , 7-11
<= , 7-10
. <= , 7-12
__altnam, 29-259
__output, 29-259, 29-535, 29-847
__title, 29-259
__Tol, 29-259
_eqs_IterInfo, 29-259
_eqs_JacobianProc, 29-259
_eqs_MaxIters, 29-259
_eqs_StepTol, 29-259
_eqs_TypicalF, 29-259
_eqs_TypicalX, 29-259
_loess_Degree, 29-535
_loess_NumEval, 29-535
_loess_Span, 29-535
Index
# , 19-3, 29-137, 29-546, 29-720, 29-956
$ , 29-137, 29-546, 29-720, 29-956
∼ , 7-19
$| , 7-18
$+ , 7-17
& , 7-17, 8-10
= , 6-2, 6-12, 6-39
= , 7-15
Index-1
Index
_loess_WgtType, 29-535
_sqp_A, 29-845
_sqp_B, 29-845
_sqp_Bounds, 29-846
_sqp_C, 29-845
_sqp_D, 29-845
_sqp_DirTol, 29-847
_sqp_EqProc, 29-845
_sqp_FeasibleTest, 29-847
_sqp_GradProc, 29-846
_sqp_HessProc, 29-847
_sqp_IneqProc, 29-846
_sqp_MaxIters, 29-847
_sqp_ParNames, 29-847
_sqp_PrintIters, 29-847
_sqp_RandRadius, 29-847
A
abs, 29-1
absolute value, 29-1
acf, 29-2
aconcat, 11-4, 29-3
additive sequence, 29-794
aeye, 11-6, 29-5
algebra, linear, 28-5
amax, 11-25, 29-6
amean, 11-25, 29-8
AmericanBinomCall, 29-10
AmericanBinomCall_Greeks, 29-11
AmericanBinomCall_ImpVol, 29-13
AmericanBinomPut, 29-14
AmericanBinomPut_Greeks, 29-15
AmericanBinomPut_ImpVol, 29-17
AmericanBSCall, 29-18
AmericanBSCall_Greeks, 29-19
AmericanBSCall_ImpVol, 29-20
AmericanBSPut, 29-21
Index-2
AmericanBSPut_Greeks, 29-22
AmericanBSPut_ImpVol, 29-23
amin, 11-25, 29-24
ampersand, 7-17
amult, 11-23, 29-26
and, 7-13, 7-14
.and, 7-15
annualTradingDays, 29-28
append, ATOG command, 24-3
arccos, 29-29
arcsin, 29-30
areshape, 11-2, 29-31
arguments, 6-40, 8-3, 8-7
array indexing, 10-3
arrayalloc, 11-7, 29-32
arrayindex, 29-33
arrayinit, 11-6, 29-34
arrays, 10-1, 11-1, 28-30
arrays of structures, 12-4
arraytomat, 11-28, 29-35
arrows, 21-14, 21-16
ASCII files, 24-1
ASCII files, packed, 24-8
ASCII files, reading, 17-3
ASCII files, writing, 17-4
asciiload, 29-36
asclabel, 29-37
assigning to arrays, 11-8
assignment operator, 6-2, 6-39, 7-15
astd, 29-38
astds, 29-40
asum, 29-42
atan, 29-44
atan2, 29-45
atog, 17-3
ATOG, 24-1
atranspose, 11-21, 29-46
Index
autocompletion, 3-12
autoindenting, 3-12
autoloader, 6-4, 6-5, 15-1, 29-509
autoreload, 3-20
auxiliary output, 17-4, 29-605
auxiliary output, width, 29-608
axes, 21-17, 21-19
axes numbering, 21-26
axes, reversed, 29-978, 29-981
axmargin, 29-49
B
C
call, 29-67
calling a procedure, 8-6
caret, 7-6, 7-19
Cartesian coordinates, 29-979
case, 6-38, 29-541, 29-940
Cauchy, 29-78, 29-614
cdBbeta, 29-68
cdfBetaInv, 29-70
commandnamecdfBinomial, 29-70
commandnamecdfBinomialInv, 29-71
cdfBvn, 29-72
cdfBvn2, 29-74
cdfBvn2e, 29-76
cdfCauchy, 29-78
cdfCauchyInv, 29-78
cdfChic, 29-79
cdfChii, 29-80
cdfChinc, 29-81
commandnamecdfChincInv, 29-83
cdfExp, 29-83
cdfExpInv, 29-84
cdfFc, 29-85
cdfFnc, 29-87
commandnamecdfFncInv, 29-88
cdfGam, 29-89
cdfGenPareto, 29-91
cdfLaplace, 29-91
cdfLaplaceInv, 29-92
cdfLogistic, 29-93
cdfLogisticInv, 29-94
Index-3
Index
backslash, 6-22
balance, 29-50
band, 29-51
bandchol, 29-52
bandcholsol, 29-53
bandltsol, 29-55
bandrv, 29-56
bandsolpd, 29-58
bar shading, 21-17
bar width, 21-18
bar, 29-58
base10, 29-60
batch mode, 5-1
begwind, 29-61
besselj, 29-61
bessely, 29-62
beta function, 29-68
beta, 29-63
binary file, loading, 29-381
binary files, 17-15
bivariate Normal, 29-72
blank lines, 6-38
Boolean operators, 7-13
box, 21-18
box, 29-64
boxcox, 29-65
branching, 28-44
break, 29-66
breakpoints, 3-22
browse, 5-5
Index
cdfm.src, 29-96, 29-97, 29-98, 29-100,
29-102, 29-104
cdfMvn, 29-94
cdfMvn2e, 29-97
cdfMvnce, 29-95
cdfMvne, 29-96
cdfMvt2e, 29-103
cdfMvtce, 29-99
cdfMvte, 29-101
cdfN, 29-105
cdfN2, 29-108
cdfNc, 29-105
commandnamecdfNegBinomial, 29-107
commandnamecdfNegBinomialInv, 29-108
cdfNi, 29-110
commandnamecdfPoisson, 29-110
commandnamecdfPoissonInv, 29-111
cdfRayleigh, 29-112
cdfRayleighInv, 29-113
cdfTc, 29-113
cdfTci, 29-115
cdfTnc, 29-116
cdfTvn, 29-117
cdfWeibull, 29-118
cdfWeibullInv, 29-119
cdir, 29-120
ceil, 29-120
change font, 3-3
change working directory, 3-3
ChangeDir, 29-121
characteristic polynomial, 29-623
chdir, 29-122
chi-square, 29-79
chi-square, noncentral, 29-81
chiBarSquare, 29-122
chol, 29-124
choldn, 29-125
Index-4
Cholesky decomposition, 0-1, 7-5, 29-124,
29-810
cholsol, 29-126
cholup, 29-127
chrs, 29-128
circles, 21-22
clear breakpoints, 3-21
clear working directory history, 3-3
clear, 29-129
clearg, 29-130
close, 3-10
close all, 3-10
close, 29-130
closeall, 29-132
cls, 29-134
code (dataloop), 29-137
code folding, 3-12
code, 29-134
coefficient of determination, 29-584, 29-589
coefficients, 29-583, 29-589
coefficients, standardized, 29-583, 29-589
colon, 6-39
color, 21-19, 21-25
Colors, 0-1
colors, 0-1
cols, 29-138
colsf, 29-139
columns in a matrix, 29-138
combinate, 29-139
combinated, 29-140
comlog, 29-142
comma, 7-16
command, 6-2
command history toolbar, 3-5
command history window, 3-7
command input window, 3-8, 3-16
command line, 5-1
Index
contour, 29-155
control flow, 6-31
control structures, 12-22
conv, 29-156
conversion, character to ASCII value, 29-945
conversion, float to ASCII, 29-336, 29-337
conversion, string to floating point, 29-862
convertsatostr, 29-157
convertstrtosa, 29-157
convolution, 29-156
coordinates, 21-6
copy, 3-3, 3-4
correlation matrix, 29-158, 29-159, 29-584,
29-589
corrm, 29-158
corrms, 29-159
corrvc, 29-158
corrx, 29-158
corrxs, 29-159
cos, 29-159
cosh, 29-160
cosine, inverse, 29-29
counts, 29-161
countwts, 29-163
create, 29-164
cropping, 21-19
cross-product, 29-170, 29-568
crossprd, 29-170
Crout decomposition, 29-171, 29-172
Crout LU decomposition, 0-1
crout, 29-171
croutp, 29-172
csrcol, 29-174
csrlin, 29-174
cumprodc, 29-175
cumsumc, 29-176
cumulative distribution function, 29-68
Index-5
Index
command line editing, 3-8, 5-2
command line history, 3-8, 5-2
command page, 3-2, 4-3
command page toolbar, 3-4
comments, 6-38
comparison functions, 29-299, 29-300
comparison operator, 6-40
compilation phase, 19-3
compile, 16-1
compile time, 6-1
compile, 29-143
compiled language, 6-1
compiler, 16-1
compiler directives, 28-42
compiling, 28-48
compiling files, 16-2
compiling programs, 16-2
complex constants, 6-14, 29-194, 29-503,
29-862
complex modulus, 29-1
complex, 24-4, 29-144
components and usage, 3-21
con, 29-145
concatenation, matrix, 7-8, 7-9
concatenation, string, 7-17
cond, 29-148
condition number, 29-148
conditional branching, 6-34
config, 5-5
conformability, 7-1
conj, 29-149
cons, 29-150
ConScore, 29-150
constants, complex, 6-14, 29-194, 29-503,
29-862
continue, 29-154
contour levels, 21-22
Index
cumulative products, 29-175
cumulative sums, 29-176
cursor, 29-174, 29-534
curve, 29-177
cut, 3-3, 3-4
cvtos, 29-178
D
data coding, 28-38
data handling, 28-33
data loop, 19-1
data page, 3-16
data sets, 17-7, 28-36
data transformations, 19-1, 29-134, 29-201
data, writing, 29-965
datacreate, 29-179
datacreatecomplex, 29-181
datalist, 29-183
dataload, 29-184
dataloop translator, 5-6
dataloop, 29-185
dataopen, 29-185
datasave, 29-187
date, 21-20, 29-188
date, 23-2, 29-188
datestr, 29-189
datestring, 29-189
datestrymd, 29-190
dayinyr, 29-191
dayofweek, 29-191
debug, 3-4
debug button, 3-6
debug page, 3-20
debug, 29-192
debugger, 3-22
debugging, 5-7, 16-3, 28-50, 29-511
declare, 29-193
Index-6
delete (dataloop), 29-200
delete, 29-198
DeleteFile, 29-200
deletion, 29-229, 29-230, 29-569, 29-612
delif, 29-201
delimited, 24-1
delimited files, 17-3
delimited, hard, 24-6
delimited, soft, 24-5
denseToSp, 29-202
denseToSpRE, 29-203
denToZero, 29-204
derivatives, 29-404
derivatives, second partial, 29-425
descriptive statistics, 29-228, 29-230
design matrix, 29-205
design, 29-205
det, 29-206
determinant, 29-206
detl, 29-207
dfft, 29-208
dffti, 29-209
diag, 29-209
diagonal, 29-209
diagrv, 29-210
differentiation, 28-3
digamma, 29-211
dimension index, 10-2
dimension number, 10-2
directory, 29-120
division, 7-5
dlibrary, 18-1, 29-212
dllcall, 18-1, 29-213
do loop, 6-32
do until, 29-215
do while, 29-215
dos, 29-218
Index
Durbin-Watson statistic, 29-583, 29-587
dynamic libraries, 18-3
E
E×E conformable, 7-1
ed, 29-246
edit, 3-4
edit button, 3-6
edit symbol, 3-16
edit, 29-247
editor, 29-247
editor properties, 3-15
editor, alternate, 29-246
eig, 29-249
eigenvalues, 28-9, 29-249
eigenvalues and eigenvectors, 29-252
eigh, 29-250
eighv, 29-251
eigv, 29-252
elapsedTradingDays, 29-254
element-by-element conformability, 7-1,
10-5
element-by-element operators, 7-1
else, 29-431
elseif, 29-431
empty matrix, 6-15, 29-138, 29-504, 29-525,
29-772, 29-784
end of file, 29-258
end, 29-254
endp, 8-2, 8-5, 29-255
endwind, 29-256
envget, 29-257
environment, search, 29-257
eof, 29-258
eq, 7-10
.eq, 7-12
eqSolve, 29-259
Index-7
Index
doswin, 29-220
DOSWinCloseall, 29-220
DOSWinOpen, 29-221
dot relational operator, 7-11, 7-21
dotmtfeq, 29-223
dotmtfeqmt, 29-224
dotfge, 29-223
dotfgemt, 29-224
dotfgt, 29-223
dotfgtmt, 29-224
dotfle, 29-223
dotflemt, 29-224
dotflt, 29-223
dotfltmt, 29-224
dotfne, 29-223
dotfnemt, 29-224
draw, 29-226
drop (dataloop), 29-227
DS structure, 12-15, 13-7
dsCreate, 29-228
dstat, 29-228
dstatmt, 29-230
dstatmtControlCreate, 29-232
dtdate, 29-233
dtday, 29-233
dttime, 29-234
dttodtv, 29-235
dttostr, 29-236
dttoutc, 29-238
dtv vector, 23-3
dtvnormal, 23-3, 29-238
dtvtodt, 29-239
dtvtoutc, 29-240
dummy variables, 29-242
dummy, 29-241
dummybr, 29-243
dummydn, 29-245
Index
eqSolvemt, 29-263
eqSolvemtControlCreate, 29-267
eqSolvemtOutCreate, 29-268
eqSolveSet, 29-269
eqv, 7-14, 7-15
.eqv, 7-15
erf, 29-269
erfc, 29-269
erfccplx, 29-271
ervCInv, 29-248
erfcplx, 29-271
ervInv, 29-248
error bar, 21-20
error code, 29-271, 29-784
error function, 29-269
error handling, 28-50
error messages, 25-1, 29-273, 29-511
error output window, 3-9, 3-16
error trapping, 29-924
error, 29-271
errorlog, 29-272
errorlogat, 29-273
escape character, 6-22
etdays, 29-273
ethsec, 29-274
etstr, 23-5, 29-275
EuropeanBinomCall, 29-276
EuropeanBinomCall_Greeks, 29-277
EuropeanBinomCall_ImpVol, 29-279
EuropeanBinomPut, 29-280
EuropeanBinomPut_Greeks, 29-281
EuropeanBinomPut_ImpVol, 29-283
EuropeanBSCall, 29-284
EuropeanBSCall_Greeks, 29-285
EuropeanBSCall_ImpVol, 29-286
EuropeanBSPut, 29-287
EuropeanBSPut_Greeks, 29-288
Index-8
EuropeanBSPut_ImpVol, 29-289
exctsmpl, 29-290
exec, 29-291
execbg, 29-292
executable code, 6-4
executable statement, 6-3
execution phase, 19-4
execution time, 6-1
exit, 3-3
exp, 29-293
exponential, 29-83, 29-84, 29-615
exponential function, 29-293
exponentiation, 7-6
export files, graphics editor, 22-16
expression, 6-1
expression, evaluation order, 6-30
expression, scalar, 6-32
extern (dataloop), 29-294
external, 29-295
extraneous spaces, 6-38
eye, 29-297
F
F distribution, 29-85, 29-87
factorial, 7-6
FALSE, 6-32
fcheckerr, 29-297
fclearerr, 29-298
feq, 29-299
feqmt, 29-300
fflush, 29-302
fft, 29-302
fft, 29-302
ffti, 29-303
fftm, 29-304
fftmi, 29-307
fftn, 29-309
Index
forward reference, 15-2
Fourier transform, 29-302
Fourier transform, discrete, 29-208, 29-209
fourier transforms, 28-10
fputs, 29-332
fputst, 29-333
fseek, 29-333
fstrerror, 29-335
ftell, 29-336
ftocv, 29-336
ftos, 29-337
ftostrC, 29-341
function, 6-37, 29-477, 29-646
functions, 28-46
fuzzy conditional functions, 28-12
G
gamma function, 29-342
gamma, 29-342
gamma, incomplete, 29-89
gamma, log, 29-519
gammacplx, 29-343
gammaii, 29-344
GAUSS Data Archives, 17-11, 17-24, 28-35
Gauss-Legendre quadrature, 29-458
gausset, 27-6, 29-344
gdaAppend, 29-345
gdaCreate, 29-346
gdaDStat, 29-347
gdaDStatMat, 29-349
gdaGetIndex, 29-352
gdaGetName, 29-353
gdaGetNames, 29-354
gdaGetOrders, 29-354
gdaGetType, 29-355
gdaGetTypes, 29-356
gdaGetVarInfo, 29-357
Index-9
Index
fge, 29-299
fgemt, 29-300
fgets, 29-311
fgetsa, 29-312
fgetsat, 29-312
fgetst, 29-313
fgt, 29-299
fgtmt, 29-300
file formats, 17-14
file handle, 29-167, 29-598
file management, graphics editor, 22-16
fileinfo, 29-314
files, 17-3
files, binary, 17-15
files, matrix, 17-13
files, string, 17-16
filesa, 29-315
finance functions, 28-23
find and replace, 3-14
fle, 29-299
flemt, 29-300
floor, 29-316
flow control, 6-31
flt, 29-299
fltmt, 29-300
fmod, 29-317
fn, 29-318
fne, 29-299
fnemt, 29-300
fonts, 0-1, 29-319
fonts, 29-318
fopen, 29-319
for, 29-321
Foreign Language Interface, 18-1
format, 29-323
formatcv, 29-330
formatnv, 29-331
Index
gdaIsCplx, 29-359
gdaLoad, 29-359
gdaPack, 29-362
gdaRead, 29-363
gdaReadByIndex, 29-364
gdaReadSome, 29-365
gdaReadSparse, 29-366
gdaReadStruct, 29-367
gdaReportVarInfo, 29-368
gdaSave, 29-370
gdaUpdate, 29-372
gdaUpdateAndPack, 29-373
gdaVars, 29-374
gdaWrite, 29-375
gdaWrite32, 29-376
gdaWriteSome, 29-377
ge, 7-11
.ge, 7-12
generalized inverse, 29-469, 29-621, 29-622
Generalized Pareto, 29-91, 29-616
getarray, 29-380
getArray, 11-12
getdims, 29-380
getDims, 11-27
getf, 29-381
getmatrix, 29-382
getMatrix, 11-13
getmatrix4D, 29-383
getMatrix4D, 11-13
getname, 29-384
getnamef, 29-385
getNextTradingDay, 29-386
getNextWeekDay, 29-387
getnr, 29-387
getnrmt, 29-388
getOrders, 11-27
getorders, 29-389
Index-10
getpath, 29-390
getPreviousTradingDay, 29-390
getPreviousWeekDay, 29-391
getRow, 29-391
getScalar3D, 11-14
getscalar3D, 29-392
getScalar4D, 11-14
getscalar4D, 29-393
getTrRow, 29-394
getwind, 29-394
global control variables, 27-5
global variable, 8-3
go, 3-20
Goertzel algorithm, 29-208
gosub, 29-395
goto help, 3-3
goto, 29-398
gradcplx, 29-404
gradient, 29-404
gradMT, 29-399
gradMTm, 29-400
gradMTT, 29-401
gradMTTm, 29-403
gradp, 29-404
graphic panels, 21-7
graphic panels, nontransparent, 21-8
graphic panels, overlapping, 21-7
graphic panels, tiled, 21-7
graphic panels, transparent, 21-8
graphical objects, graphics editor, 22-11
graphics editor, 22-1
graphics, publication quality, 21-1
graphprt, 29-405
graphset, 29-408
grid, 21-21
grid subdivisions, 21-21
gt, 7-11
Index
.gt, 7-12
H
I
if, 29-431
imag, 29-432
imaginary matrix, 29-432
inch coordinates, 21-6
#include, 29-433
incomplete beta function, 29-68
incomplete gamma function, 29-89
indcv, 29-434
indefinite, 6-28
index variables, 29-597
indexcat, 29-435
indexing matrices, 6-40, 7-16
indexing procedures, 7-17
indexing, array, 10-3
indexing, structure, 12-5
indices, 29-437
indices2, 29-438
indicesf, 29-439
indicesfn, 29-440
indnv, 29-441
indsav, 29-442
infinity, 6-28
initialize, 8-4
initializing arrays, 11-1
inner product, 7-5
input, ATOG command, 24-4
input, console, 29-145
input, keyboard, 29-145
installation, 2-1
installation, UNIX/Linux, 2-1
installation, Windows, 2-2
instruction pointer, 6-3
Index-11
Index
hard delimited, 24-6
hasimag, 29-408
hat operator, 7-6, 7-19
header, 29-410
headermt, 29-410
help facility, 29-511
help hot keys, 3-25
help page, 3-25
help, F1, 4-4
hermitian matrix, 29-251
hess, 29-411
hesscplx, 29-425
Hessian, 29-425
hessMT, 29-413
hessMTg, 29-414
hessMTgw, 29-415
hessMTm, 29-416
hessMTmw, 29-418
hessMTT, 29-419
hessMTTg, 29-420
hessMTTgw, 29-421
hessMTTm, 29-423
hessMTw, 29-424
hessp, 29-425
hidden lines, 21-27
hist, 29-427
histf, 29-428
histogram, 29-427, 29-428
histp, 29-429
horizontal direct product, 7-7
hot keys, 4-2
hot keys, programming editor, 3-12
hsec, 29-430
html, 3-21
hyperbolic cosine, 29-160
hyperbolic sine, 29-808
hyperbolic tangent, 29-910
Index
integration, 28-3, 28-4, 29-447, 29-450,
29-452, 29-455, 29-458, 29-466
interactive commands, 5-4
interpreter, 6-1
intersection, 29-465
intgrat2, 29-443
intgrat3, 29-445
inthp1, 29-447
inthp2, 29-449
inthp3, 29-452
inthp4, 29-455
inthpControlCreate, 29-458
intquad1, 29-458
intquad2, 29-460
intquad3, 29-461
intrinsic function, 6-8
intrleav, 29-463
intrleavsa, 29-464
intrsect, 29-465
intrsectsa, 29-466
intsimp, 29-466
inv, 29-467
invar, ATOG command, 24-5
inverse cosine, 29-29
inverse sine, 29-30
inverse, generalized, 29-469, 29-621, 29-622
inverse, matrix, 29-467
inverse, sweep, 29-469
invpd, 29-467
invswp, 29-469
iscplx, 29-470
iscplxf, 29-471
isden, 29-471
isinfnanmiss, 29-472
ismiss, 29-472
Index-12
J
Jacobian, 29-404
K
keep (dataloop), 29-473
key, 29-474
keyav, 29-476
keyboard input, 29-150
keyboard, reading, 29-474
keyw, 29-476
keyword, 8-1, 8-7
keyword procedure, 29-477
keyword, 29-477
keywords, 28-46
Kronecker, 7-6
L
label, 6-35, 6-39, 8-1, 29-395, 29-398
lag (dataloop), 29-478
lag1, 29-479
lagn, 29-479
lambda, 29-82
lapeighb, 29-480
lapeighi, 29-481
lapeigvb, 29-482
lapeigvi, 29-484
lapgeig, 29-485
lapgeigh, 29-486
lapgeighv, 29-487
lapgeigv, 29-488
lapgschur, 29-497
lapgsvdcst, 29-489
lapgsvds, 29-492
lapgsvdst, 29-494
Laplace, 29-91, 29-92, 29-616
lapsvdcusv, 29-498
Index
lnfact, 29-519
lngammacplx, 29-520
lnpdfmvn, 29-521
lnpdfmvt, 29-522
lnpdfn, 29-522
lnpdft, 29-523
load, 29-524
loadarray, 29-529
loadd, 29-531
loadf, 29-524
loadk, 29-524
loadm, 29-524
loadp, 29-524
loads, 29-524
loadstruct, 29-532
loadwind, 29-532
local variable declaration, 8-3
local variables, 6-8, 8-3, 29-533
local, 8-2, 29-533
locate, 29-534
loess, 29-534
loessmt, 29-535
loessmtControlCreate, 29-536
log coordinates, 29-538
log factorial, 29-519
log gamma, 29-519
log, 29-537
log, base 10, 29-537
log, natural, 29-513
logging commands, 29-142
logical operators, 7-13
logistic, 29-93, 29-94, 29-617
loglog, 29-538
logx, 29-538
logy, 29-539
looping, 6-32, 28-45, 29-215
looping with arrays, 11-17
Index
lapsvds, 29-500
lapsvdusv, 29-501
layout, 3-6, 3-18
layout and usage, 3-10
le, 7-10
.le, 7-12
least squares, 7-5
least squares regression, 29-580, 29-585
left-hand side, 15-2
legend, 21-22
let, 29-502
lib, 29-507
libraries, 15-1, 28-47
libraries, active, 29-509
library, 29-508
line numbers, 29-511
line thickness, 21-16, 21-20, 21-25
line type, 21-25
linear algebra, 28-5
linear equation, 29-809
linear equation solution, 7-5
lines, 21-21, 21-22, 21-24
#linesoff, 29-511
#lineson, 29-511
linsolve, 29-512
listwise (dataloop), 29-513
listwise deletion, 29-229, 29-230, 29-569,
29-612
literal, 6-23, 7-19
ln, 29-513
lncdfbvn, 29-514
lncdfbvn2, 29-515
lncdfmvn, 29-517
lncdfn, 29-517
lncdfn.src, 29-94, 29-109
lncdfn2, 29-518
lncdfnc, 29-519
Index-13
Index
loopnextindex, 11-19, 29-540
lower triangular matrix, 29-542
lower, 29-541
lowmat, 29-542
lowmat1, 29-542
lt, 7-10
.lt, 7-11
ltrisol, 29-543
LU decomposition, 7-5, 29-544
lu, 29-544
lusol, 29-545
M
machEpsilon, 29-545
machine epsilon, 29-105, 29-902, 29-907
machine requirements, 2-2
magnification, 21-29
make (dataloop), 29-546
makevars, 29-546
makewind, 29-548
margin, 29-549
matalloc, 29-550
matinit, 29-551
matrices, indexing, 6-40
matrix conformability, 7-1
matrix files, 17-13
matrix manipulation, 28-24
matrix, creation, 29-502
matrix, empty, 6-15, 29-138, 29-504, 29-525,
29-772, 29-784
matrix, ones, 29-595
matrix, zeros, 29-981
mattoarray, 11-28, 29-551
maxbytes, 29-556
maxc, 29-552
maximizing performance, 26-1
maximum element, 29-552
Index-14
maximum element index, 29-553
maxindc, 29-553
maxv, 29-554
maxvec, 29-555
mbesseli, 29-556
mean, 29-559
meanc, 29-559
median, 29-560
memory, 29-199
memory, clear all, 29-574
menu bar, 3-16
menu, edit, 3-3
menu, file, 3-3, 3-10
menu, help, 3-3
menu, symbol editor, 3-16
menu, tools, 3-3
menu, view, 3-3
menu, window, 3-10, 3-17
menus, 3-3, 3-20
menus, graphics editor, 22-4
mergeby, 29-561
mergevar, 29-562
merging, 28-41
minc, 29-563
minimum element, 29-563
minimum element index, 29-564
minindc, 29-564
minv, 29-565
miss, 29-566
missex, 29-567
missing character, 29-573
missing values, 7-5, 29-229, 29-230, 29-472,
29-566, 29-567, 29-573, 29-612,
29-786
missrv, 29-566
modulo division, 7-5
moment matrix, 29-569, 29-583, 29-588
Index
moment, 29-568
momentd, 29-570
Moore-Penrose pseudo-inverse, 29-621,
29-622
movement, command line history, 3-8
movingave, 29-571
movingaveExpwgt, 29-572
movingaveWgt, 29-573
msym, 29-573
msym, ATOG command, 24-10
multi-threading, 14-1, 28-43
multiplication, 7-5
multiplicative sequence, 29-794
N
O
obsolete commands, 0-1
ols, 29-580
olsmt, 29-585
olsmtControlCreate, 29-592
olsqr, 29-593
olsqr2, 29-594
olsqrmt, 29-595
ones, 29-595
open, 3-3, 3-4
open, 29-596
operators, 6-1, 7-4
operators, element-by-element, 7-1
optimization, 28-17
optn, 29-602
optnevn, 29-602
or, 7-13, 7-14
.or, 7-15
orth, 29-604
orthogonal complement, 29-578
orthonormal, 29-578, 29-604
outer product, 7-6
output, 17-4
output functions, 28-56
output, 29-604
output, ATOG command, 24-10
outtyp (dataloop), 29-608
outtyp, ATOG command, 24-11
outvar, ATOG command, 24-11
outwidth, 29-608
P
pacf, 29-609
Index-15
Index
N-dimensional arrays, 10-1, 11-1, 28-30
NaN, 6-28
NaN, testing for, 6-29, 7-9
navigating, 4-2
ne, 7-11
.ne, 7-12
new, 3-3, 3-4, 3-18
new, 29-574
nextindex, 29-575
nextn, 29-576
nextnevn, 29-576
nextwind, 29-577
nocheck, 24-10
Normal distribution, 29-94, 29-95, 29-96,
29-97, 29-99, 29-101, 29-103,
29-105, 29-108, 29-514, 29-517,
29-518, 29-519
Normal distribution, bivariate, 29-72
not, 7-13, 7-14
.not, 7-15
null space, 29-578
null, 29-578
null1, 29-579
numCombinations, 29-580
Index
packed ASCII, 24-1, 24-8
packedToSp, 29-610
packr, 29-612
page organization, 3-1
_pageshf, 21-14
_pagesiz, 21-14
pairwise deletion, 7-5, 29-229, 29-230,
29-569
panel data, 11-32
_parrow, 21-14
_parrow3, 21-16
parse, 29-613
paste, 3-3, 3-4, 3-5
pause, 29-614
_paxes, 21-17
_paxht, 21-17
_pbartyp, 21-17
_pbarwid, 21-18
_pbox, 21-18
_pboxlim, 21-19
_pcolor, 21-19
_pcrop, 21-19
_pcross, 21-19
_pdate, 21-20
pdfCauchy, 29-614
pdfexp, 29-615
pdfGenPareto, 29-616
pdfLaplace, 29-616
pdflogistic, 29-617
pdfn, 29-618
pdfRayleigh, 29-619
pdfWeibull, 29-619
_perrbar, 21-20
_pframe, 21-20
_pgrid, 21-21
pi, 29-620
pinv, 29-621
Index-16
pinvmt, 29-622
pixel coordinates, 21-6
_plctrl, 21-21
_plegctl, 21-22
_plegstr, 21-22
_plev, 21-22
_pline, 21-22
_pline3d, 21-24
plot coordinates, 21-6
_plotshf, 21-24
_plotsiz, 21-25
_pltype, 21-25
_plwidth, 21-25
_pmcolor, 21-25
_pmsgctl, 21-26
_pmsgstr, 21-26
_pnotify, 21-26
_pnum, 21-26
_pnumht, 21-27
pointer, 7-17, 8-10, 8-11, 29-533
pointer, instruction, 6-3
pointers, structure, 12-10
polar, 29-623
polychar, 29-623
polyeval, 29-624
polygamma, 29-625
polyint, 29-626
polymake, 29-627
polymat, 29-628
polymroot, 29-628
polymult, 29-630
polynomial, 29-627
polynomial interpolation, 29-626
polynomial operations, 28-10
polynomial regression, 29-628
polynomial, characteristic, 29-623
polynomial, evaluation, 29-624
Index
_psilent, 21-27
_pstype, 21-27
_psurf, 21-27
_psym, 21-28
_psym3d, 21-28
_psymsiz, 21-28
_ptek, 21-28
_pticout, 21-28
_ptitlht, 21-28
Publication Quality Graphics, 21-1, 28-57
putArray, 11-15
putarray, 29-649
putf, 29-650
putvals, 29-651
PV structure, 12-16, 13-1
pvCreate, 29-653
_pversno, 21-29
pvGetIndex, 29-653
pvGetParNames, 29-654
pvGetParVector, 29-655
pvLength, 29-656
pvList, 29-656
pvPack, 29-657
pvPacki, 29-658
pvPackm, 29-659
pvPackmi, 29-660
pvPacks, 29-662
pvPacksi, 29-663
pvPacksm, 29-664
pvPacksmi, 29-666
pvPutParVector, 29-668
pvTest, 29-670
pvUnpack, 29-670
_pxpmax, 21-29
_pxsci, 21-29
_pypmax, 21-29
_pysci, 21-29
Index-17
Index
polynomial, roots, 29-631
polyroot, 29-631
pop, 29-631
pqgwin, 29-632
precedence, 6-30
precision control, 28-22
predicted values, 29-594
preferences, 3-3, 3-17
preservecase, 24-12
previousindex, 29-633
princomp, 29-634
print, 3-3, 3-4
print setup, 3-3
print, 29-635
printdos, 29-641
printfm, 29-642
printfmt, 29-645
probability density function, Normal, 29-618
proc, 8-2, 29-646
procedure, 8-1, 29-533, 29-646
procedure, definitions, 6-3, 8-2
procedures, 28-46
procedures, indexing, 8-10
procedures, multiple returns, 8-11
procedures, passing to other procedures, 8-9
prodc, 29-647
products, 29-648
Profiler, 20-1
program, 6-4
program control, 28-44
program space, 29-804
program, run, 29-774
programming editor, 3-10
_protate, 21-27
_pscreen, 21-27
pseudo-inverse, 29-621, 29-622
psi, 29-648
Index
_pzclr, 21-29
_pzoom, 21-29
_pzpmax, 21-29
_pzsci, 21-29
Q
QNewton, 29-671
QNewtonmt, 29-674
QNewtonmtControlCreate, 29-678
QNewtonmtOutCreate, 29-679
QNewtonSet, 29-679
QProg, 29-680
QProgmt, 29-681
QProgmtInCreate, 29-684
qqr, 29-684
qqre, 29-686
qqrep, 29-689
QR decomposition, 29-593, 29-595
qr, 29-691
qre, 29-692
qrep, 29-695
qrsol, 29-697
qrtsol, 29-698
qtyr, 29-698
qtyre, 29-701
qtyrep, 29-704
quadrature, 29-458
quantile, 29-706
quantiled, 29-707
qyr, 29-709
qyre, 29-710
qyrep, 29-712
R
radii, 21-22
random numbers, 28-11
Index-18
rank of a matrix, 29-714
rank, 29-714
rankindx, 29-715
Rayleigh, 29-112, 29-113, 29-619
readr, 29-716
real, 29-717
recent files, 3-3
recent working directories, 3-3
recode (dataloop), 29-720
recode, 29-718
recserar, 29-721
recsercp, 29-723
recserrc, 29-724
recursion, 8-5
redo, 3-3
reduced row echelon form, 29-773
regression, 29-580, 29-585
regular expressions, 3-14
relational operator, dot, 7-11, 7-21
relational operators, 7-9
relative error, 29-105, 29-114
reload, 3-18
reload symbol, 3-16
remove split, 3-10
rerun, 29-725
reserved words, 0-1
reshape, 29-726
residuals, 29-583, 29-587, 29-594
retp, 8-2, 8-5, 29-727
return, 29-728
rev, 29-728
rfft, 29-729
rffti, 29-730
rfftip, 29-731
rfftn, 29-732
rfftnp, 29-733
rfftp, 29-735
Index
run button, 3-6
run to cursor, 3-21
run, 29-774
Run-Time Library structures, 13-1
S
satostrC, 29-776
save, 3-10, 3-18
save as, 3-10
save symbol, 3-16
save, 29-776
saveall, 29-778
saved, 29-779
savestruct, 29-780
savewind, 29-781
saving the workspace, 16-2
scalar error code, 29-271, 29-784
scalar expression, 6-32
scale, 29-782
scale3d, 29-783
scalerr, 29-784
scalinfnanmiss, 29-785
scaling, 29-782, 29-783
scalmiss, 29-786
schtoc, 29-787
schur, 29-788
scientific functions, 28-1
screen, 29-789
search next, 3-5
search previous, 3-5
searchsourcepath, 29-790
secondary section, 6-5
seekr, 29-791
select (dataloop), 29-792
selif, 29-792
semicolon, 6-2
seqa, 29-794
Index
right-hand side, 15-2
rndbeta, 29-736
rndcon, 29-737
rndgam, 29-738
rndi, 29-740
rndKMbeta, 29-740
rndKMgam, 29-742
rndKMi, 29-743
rndKMn, 29-745
rndKMnb, 29-746
rndKMp, 29-747
rndKMu, 29-749
rndKMvm, 29-750
rndLCbeta, 29-751
rndLCgam, 29-753
rndLCi, 29-755
rndLCn, 29-757
rndLCnb, 29-758
rndLCp, 29-760
rndLCu, 29-762
rndLCvm, 29-764
rndmult, 29-737
rndn, 29-765
rndnb, 29-766
rndp, 29-767
rndseed, 29-737
rndu, 29-768
rndvm, 29-769
rotater, 29-770
round down, 29-316
round up, 29-121
round, 29-771
rows, 29-771
rowsf, 29-772
rref, 29-773
rules of syntax, 6-37
run, 3-4, 3-5
Index-19
Index
seqm, 29-794
sequence function, 29-794
sequence functions, 28-22
series functions, 28-22
set difference function, 29-796
setArray, 11-16
setarray, 29-795
setdif, 29-796
setdifsa, 29-797
setvars, 29-798
setvwrmode, 29-799
setwind, 29-800
shell, 29-800
shiftr, 29-801
shortcuts, 4-2
show, 29-802
Simpson’s method, 29-466
sin, 29-805
sine, inverse, 29-30
singleindex, 29-806
singular value decomposition, 29-888,
29-890, 29-892
singular values, 29-887, 29-891
singularity tolerance, 0-1
sinh, 29-808
sleep, 29-809
soft delimited, 24-5
solpd, 29-809
sort data file, 29-812
sort index, 29-815
sort, heap sort, 29-813
sort, multiple columns, 29-816
sort, quicksort, 29-811
sortc, 29-811
sortcc, 29-811
sortd, 29-812
sorthc, 29-813
Index-20
sorthcc, 29-813
sortind, 29-815
sortindc, 29-815
sorting, 28-41
sortmc, 29-816
sortr, sortrc, 29-817
Source Browser, 5-10
source browsing, 4-4
source page, 3-9
spaces, 7-16
spaces, extraneous, 6-38, 7-16, 7-17
sparse matrices, 28-29
spBiconjGradSol, 29-818
spChol, 29-820
spConjGradSol, 29-821
spCreate, 29-822
spDenseSubmat, 29-824
spDiagRvMat, 29-825
spEigv, 29-827
spEye, 29-829
spGetNZE, 29-829
spLDL, 29-832
spline, 29-831
split horizontally, 3-10, 3-17
split vertically, 3-10, 3-17
spLU, 29-833
spNumNZE, 29-835
spOnes, 29-836
SpreadsheetReadM, 29-837
SpreadsheetReadSA, 29-837
spreadsheets, 28-33
SpreadsheetWrite, 29-838
spScale, 29-839
spSubmat, 29-840
spToDense, 29-841
spTrTDense, 29-842
spTScalar, 29-842
Index
strindx, 29-864
string array concatenation, 7-18
string arrays, 6-24, 6-25
string concatenation, 7-17
string files, 17-16
string handling, 28-51
string index, 29-864, 29-866
string length, 29-865
string, long, 6-38
string, substring, 29-867
strings, graphics, 21-26
strlen, 29-865
strput, 29-865
strrindx, 29-866
strsect, 29-867
strsplit, 29-868
strsplitPad, 29-869
strtodt, 29-871
strtof, 29-872
strtofcplx, 29-873
strtriml, 29-873
strtrimr, 29-874
strtrunc, 29-874
strtruncl, 29-875
strtruncpad, 29-875
strtruncr, 29-876
struct editor, 3-19
structure definition, 12-1
structure indexing, 12-5
structure instance, 12-2
structure pointers, 12-10
structure, DS, 12-15, 13-7
structure, PV, 12-16, 13-1
structures, 3-19, 12-1, 28-32
structures, arrays of, 12-4
structures, control, 12-22
submat, 29-876
Index
spZeros, 29-843
sqpSolve, 29-844
sqpSolvemt, 12-23
sqpSolveMT, 29-849
sqpSolvemtControl structure, 12-25
sqpSolveMTControlCreate, 29-856
sqpSolveMTlagrangeCreate, 29-857
sqpSolveMToutCreate, 29-858
sqpSolveSet, 29-858
sqrt, 29-858
square root, 29-858
src_path, 15-1
standard deviation, 29-38, 29-40, 29-229,
29-231, 29-859, 29-860
standard deviation of residual, 29-583,
29-589
standard errors, 29-583, 29-589
statement, 6-2, 6-37
statement, executable, 6-3
statement, nonexecutable, 6-3
statistical distributions, 28-18
statistical functions, 28-14
statistics, descriptive, 29-228, 29-230
status bar, graphics editor, 22-3
stdc, 29-859
stdsc, 29-860
step into, 3-21
step out, 3-21
step over, 3-21
stepping through, 3-23
Stirling’s formula, 29-520
stocv, 29-861
stof, 29-862
stop, 3-20
stop program, 3-4
stop, 29-862
strcombine, 29-863
Index-21
Index
submatrix, 29-876
subroutine, 6-36, 29-395
subroutines, 28-46
subsample, 29-290
subscat, 29-877
substitution, 7-19
substring, 29-867
substute, 29-879
subvec, 29-880
sum, 29-882
sumc, 29-881
sumr, 29-883
surface, 29-885
svd, 29-887
svd1, 29-888
svd2, 29-889
svdcusv, 29-890
svds, 29-891
svdusv, 29-892
sweep inverse, 29-469
symbol editor, 3-20
symbol names, 6-39
symbol table, 29-803
symbol table type, 29-930
symbols, allocate maximum number, 29-574
syntax, 6-37
syntax highlighting, 3-12
sysstate, 29-893
system, 29-908
T
t distribution, Student’s, 29-113
tab, 29-908
table, 7-6
tan, 29-909
tanh, 29-910
tempname, 29-911
Index-22
tensor, 7-6
text files, 28-34
TGAUSS, 5-1
thickness, line, 21-16, 21-20, 21-25
ThreadBegin, 29-911
ThreadEnd, 29-912
ThreadJoin, 29-913
threads, 14-1, 28-43
ThreadStat, 29-914
tick marks, 21-28
tilde, 7-9
time and date functions, 28-53
time, 23-2, 29-914
time, elapsed, 29-274
timed iterations, 23-6
timedt, 29-915
timestr, 29-915
timeutc, 29-916
timing functions, 29-430
title, 29-917
tkf2eps, 29-917
tkf2ps, 29-918
tocart, 29-919
todaydt, 29-919
Toeplitz matrix, 29-920
toeplitz, 29-920
toggle auto-reload, 3-17
toggle breakpoint, 3-21
token, 29-921
toolbar, 3-18
toolbar, graphics editor, 22-2
toolbars, 3-3, 3-20
tooltips, 3-12
topolar, 29-922
trace program execution, 29-922
trace, 29-922
translation phase, 19-3
Index
transpose, 7-8
transpose, bookkeeping, 7-8
trap flag, 29-924, 29-926
trap state, 29-784
trap, 29-924
trapchk, 29-926
triangular matrix, lower, 29-542
triangular matrix, upper, 29-939
trigamma, 29-928
trimr, 29-928
trivariate Normal, 29-117
troubleshooting, libraries, 15-12
TRUE, 6-32, 7-10
trunc, 29-929
truncating, 29-929
type, 29-930
typecv, 29-931
typef, 29-932
U
V
vals, 29-945
varget, 29-946
vargetl, 29-947
variable names, 29-384, 29-385
variables, debugging, 3-23, 3-24
variables, editing, 3-23
variables, viewing, 3-23
variance, 29-229, 29-231
variance-covariance matrix, 29-583, 29-589,
29-953
varindxi, 29-597
varmall, 29-948
varmares, 29-949
varput, 29-949
varputl, 29-951
vartypef, 29-952
vcm, 29-953
vcms, 29-953
vcx, 29-953
vcxs, 29-953
vec, vecr, 29-954
vech, 29-955
vector (dataloop), 29-956
vectors, 6-40
vget, 29-957
view, 29-957
viewing graphics, 5-2
viewing program output, 4-3
viewxyz, 29-958
vlist, 29-959
vnamecv, 29-959
volume, 29-960
vput, 29-960
Index-23
Index
unconditional branching, 6-35
underdetermined, 29-583, 29-589
undo, 3-3
union, 29-933
unionsa, 29-934
uniqindx, 29-935
uniqindxsa, 29-936
unique, 29-937
uniquesa, 29-938
until, 29-215
upmat, 29-939
upmat1, 29-939
upper triangular matrix, 29-939
upper, 29-940
use, 29-940
user-defined function, 29-477, 29-646
utctodt, 29-942
utctodtv, 29-943
utrisol, 29-944
Index
vread, 29-961
vtypecv, 29-962
W
wait, 29-962
waitc, 29-962
walkindex, 29-963
watch window, 3-24
Weibull, 29-118, 29-119, 29-619
weighted count, 29-163
while, 29-215
window, 17-4
window, 29-964
window, clear, 29-134
workbox, 29-958, 29-960
working directory toolbar, 3-4
workspace, 29-199, 29-804
writer, 29-965
X
xlabel, 29-966
xlsGetSheetCount, 29-967
xlsGetSheetSize, 29-968
xlsGetSheetTypes, 29-968
xlsMakeRange, 29-969
xlsReadM, 29-970
xlsReadSA, 29-971
xlsWrite, 29-973
xlsWriteM, 29-974
xlsWriteSA, 29-975
xor, 7-14
.xor, 7-15
xpnd, 29-977
xtics, 29-978
xy, 29-979
xyz, 29-979
Index-24
Y
ylabel, 29-980
ytics, 29-980
Z
zeros, 29-981
zeta, 29-982
zlabel, 29-982
zooming graphs, 21-29
ztics, 29-983

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