NAG recommends that you read the following minimum reference material before calling any library routine:
(a) Essential Introduction
(b) Chapter Introduction
(c) Routine Document
(d) Implementation-specific Users' Note
Items (a), (b) and (c) are included in the NAG Fortran Library Manual; items (a) and (b) are also included in the NAG Fortran Library Introductory Guide; item (d) is this document which is provided in HTML form. Item (a) is also supplied in plain text form.
high performance 32-bit (-n32) mode using -mips3
high performance 32-bit (-n32) mode using -mips4
64-bit mode using -mips3
64-bit mode using -mips4
You may link to the NAG Fortran Library in the following manner:
f77 driver.f -lnagor
f90 driver.f -lnagwhere driver.f is the user's application program.
The specific library used by the linker depends on the compilation options, if any, specified by the user and on the system processor. On systems such as the Silicon Graphics Power Indigo2, based on a R8000 processor, the default, if the SGI_ABI environment variable has not been set, is 64-bit and MIPS IV.
On systems such as the Silicon Graphics Origin 2000, based on a R10000 processor, the default, if the SGI_ABI environment variable has not been set, is high performance 32-bit (-n32) and MIPS IV.
To use a library that requires the Silicon Graphics BLAS and LAPACK routines, the compilation command above should be modified to
f77 driver.f -lnag_csm -lcomplib.sgimathor
f90 driver.f -lnag_csm -lcomplib_sgimath
This links to the NAG library as well as the Silicon Graphics BLAS and LAPACK routines in libcomplib.sgimath.so.
Note that the choice of the library linked to can be overridden by specifying the application binary interface (ABI), that is -n32 or -64, and the instruction set architecture (ISA), that is -mips3 or -mips4.
It may be necessary to append to the high performance 32-bit (-n32) and 64-bit default library search paths the location of the NAG libraries.
In the C shell use the command:
setenv LD_LIBRARYN32_PATH '/usr/lib32/mips3:/usr/lib32/mips4'for high performance 32-bit (-n32) programs and
setenv LD_LIBRARY64_PATH '/usr/lib64/mips3:/usr/lib64/mips4'for 64-bit programs.
In the Bourne shell the equivalent commands would be:
LD_LIBRARYN32_PATH='/usr/lib32/mips3:/usr/lib32/mips4' export LD_LIBRARYN32_PATHand
LD_LIBRARY64_PATH='/usr/lib64/mips3:/usr/lib64/mips4' export LD_LIBRARY64_PATHIf these environment variables are not set, the program may exhibit a fatal error indicating that it is not able to map successfully soname 'libnag.so'. For more information concerning runtime linker options, please refer to the 'rld' man page.
nagexample c06eafwill copy the example program and its data into the files c06eafe.f and c06eafe.d in the current directory and process them to produce the example program results.
In the NAG Fortran Library Manual, routine documents that have been typeset since Mark 12 present the example programs in a generalised form, using bold italicised terms as described in Section 3.3.
In other routine documents, the example programs are in single precision and require modification for use with double precision routines. This conversion can entail:
The example programs supplied to a site in machine-readable form have been modified as necessary so that they are suitable for immediate execution. Note that all the distributed example programs have been revised and do not correspond exactly with the programs published in the manual, unless the documents have been recently typeset. The distributed example programs should be used in preference wherever possible.
real - DOUBLE PRECISION (REAL*8) basic precision - double precision complex - COMPLEX*16 additional precision - quadruple precision (REAL*16) machine precision - the machine precision, see the value returned by X02AJF in Section 4
Thus a parameter described as real should be declared as DOUBLE PRECISION in your program. If a routine accumulates an inner product in additional precision, it is using software to simulate quadruple precision.
In routine documents that have been newly typeset since Mark 12 additional bold italicised terms are used in the published example programs and they must be interpreted as follows:
real as an intrinsic function name - DBLE imag - DIMAG cmplx - DCMPLX conjg - DCONJG e in constants, e.g. 1.0e-4 - D, e.g. 1.0D-4 e in formats, e.g. e12.4 - D, e.g. D12.4
All references to routines in Chapter F07 - Linear Equations (LAPACK) and Chapter F08 - Least-squares and Eigenvalue Problems (LAPACK) use the LAPACK name, not the NAG F07/F08 name. The LAPACK name is precision dependent, and hence the name appears in a bold italicised typeface.
The typeset examples use the single precision form of the LAPACK name. To
convert this name to its double precision form, change the first character
either from S to D or C to Z as appropriate.
For example:
sgetrf refers to the LAPACK routine name - DGETRF cpotrs - ZPOTRS
See Section 5 for additional documentation available from NAG.
(a) Subroutines are called as such
(b) Functions are declared with the right type
(c) The correct number of arguments are passed
(d) All arguments match in type and structure
These interface blocks have been generated automatically by analysing the source code for the NAG Fortran Library. As a consequence, and because these files have been thoroughly tested, they are more reliable than writing your own declarations.
The NAG Fortran Library Interface Block files are organised by Library chapter. The module names are:
nag_f77_a_chapter nag_f77_c_chapter nag_f77_d_chapter nag_f77_e_chapter nag_f77_f_chapter nag_f77_g_chapter nag_f77_h_chapter nag_f77_m_chapter nag_f77_p_chapter nag_f77_s_chapter nag_f77_x_chapterThese are supplied in pre-compiled form (.mod files) and they can be accessed by specifying the
In order to make use of these modules from existing Fortran 77 code the following changes need to be made:
These changes are illustrated by showing the conversion of the Fortran 77 version of the example program for NAG Fortran Library routine S18DEF. Please note that this is not exactly the same as the example program that is distributed with this implementation. Each change is surrounded by comments boxed with asterisks.
* S18DEF Example Program Text * Mark 14 Revised. NAG Copyright 1989. ******************************************************************* * Add USE statement for relevant chapters * USE NAG_F77_S_CHAPTER * * ******************************************************************* * .. Parameters .. INTEGER NIN, NOUT PARAMETER (NIN=5,NOUT=6) INTEGER N PARAMETER (N=2) * .. Local Scalars .. COMPLEX*16 Z DOUBLE PRECISION FNU INTEGER IFAIL, NZ CHARACTER*1 SCALE * .. Local Arrays .. COMPLEX*16 CY(N) * .. External Subroutines .. ******************************************************************* * EXTERNAL declarations need to be removed (and type declarations * * for functions). * C EXTERNAL S18DEF * * ******************************************************************* * .. Executable Statements .. WRITE (NOUT,*) 'S18DEF Example Program Results' * Skip heading in data file READ (NIN,*) WRITE (NOUT,*) WRITE (NOUT,99999) 'Calling with N =', N WRITE (NOUT,*) WRITE (NOUT,*) +' FNU Z SCALE CY(1) CY(2) + NZ IFAIL' WRITE (NOUT,*) 20 READ (NIN,*,END=40) FNU, Z, SCALE IFAIL = 0 * CALL S18DEF(FNU,Z,N,SCALE,CY,NZ,IFAIL) * WRITE (NOUT,99998) FNU, Z, SCALE, CY(1), CY(2), NZ, IFAIL GO TO 20 40 STOP * 99999 FORMAT (1X,A,I2) 99998 FORMAT (1X,F7.4,' (',F7.3,',',F7.3,') ',A, + 2(' (',F7.3,',',F7.3,')'),I4,I4) END
S07AAF F(1) = 1.0D+13 F(2) = 1.0D-14 S10AAF E(1) = 18.50 S10ABF E(1) = 708.0 S10ACF E(1) = 708.0 S13AAF x(hi) = 708.3 S13ACF x(hi) = 5.6D+14 S13ADF x(hi) = 5.6D+14 S14AAF IFAIL = 1 if X > 170.0 IFAIL = 2 if X < -170.0 IFAIL = 3 if abs(X) < 2.23D-308 S14ABF IFAIL = 2 if X > 2.55D+305 S15ADF x(hi) = 26.6 x(low) = -6.25 S15AEF x(hi) = 6.25 S17ACF IFAIL = 1 if X > 5.6D+14 S17ADF IFAIL = 1 if X > 5.6D+14 IFAIL = 3 if 0.0 < X <= 2.23D-308 S17AEF IFAIL = 1 if abs(X) > 5.6D+14 S17AFF IFAIL = 1 if abs(X) > 5.6D+14 S17AGF IFAIL = 1 if X > 103.8 IFAIL = 2 if X < -8.9D+9 S17AHF IFAIL = 1 if X > 104.1 IFAIL = 2 if X < -8.9D+9 S17AJF IFAIL = 1 if X > 104.1 IFAIL = 2 if X < -1.8D+9 S17AKF IFAIL = 1 if X > 104.1 IFAIL = 2 if X < -1.8D+9 S17DCF IFAIL = 2 if abs (Z) < 3.93D-305 IFAIL = 4 if abs (Z) or FNU+N-1 > 3.27D+4 IFAIL = 5 if abs (Z) or FNU+N-1 > 1.07D+9 S17DEF IFAIL = 2 if imag (Z) > 700.0 IFAIL = 3 if abs (Z) or FNU+N-1 > 3.27D+4 IFAIL = 4 if abs (Z) or FNU+N-1 > 1.07D+9 S17DGF IFAIL = 3 if abs (Z) > 1.02D+3 IFAIL = 4 if abs (Z) > 1.04D+6 S17DHF IFAIL = 3 if abs (Z) > 1.02D+3 IFAIL = 4 if abs (Z) > 1.04D+6 S17DLF IFAIL = 2 if abs (Z) < 3.93D-305 IFAIL = 4 if abs (Z) or FNU+N-1 > 3.27D+4 IFAIL = 5 if abs (Z) or FNU+N-1 > 1.07D+9 S18ADF IFAIL = 2 if 0.0 < X <= 2.23D-308 S18AEF IFAIL = 1 if abs(X) > 711.6 S18AFF IFAIL = 1 if abs(X) > 711.6 S18CDF IFAIL = 2 if 0.0 < X <= 2.23D-308 S18DCF IFAIL = 2 if abs (Z) < 3.93D-305 IFAIL = 4 if abs (Z) or FNU+N-1 > 3.27D+4 IFAIL = 5 if abs (Z) or FNU+N-1 > 1.07D+9 S18DEF IFAIL = 2 if real (Z) > 700.0 IFAIL = 3 if abs (Z) or FNU+N-1 > 3.27D+4 IFAIL = 4 if abs (Z) or FNU+N-1 > 1.07D+9 S19AAF IFAIL = 1 if abs(x) >= 49.50 S19ABF IFAIL = 1 if abs(x) >= 49.50 S19ACF IFAIL = 1 if X > 997.26 S19ADF IFAIL = 1 if X > 997.26 S21BCF IFAIL = 3 if an argument < 1.579D-205 IFAIL = 4 if an argument >= 3.774D+202 S21BDF IFAIL = 3 if an argument < 2.820D-103 IFAIL = 4 if an argument >= 1.404D+102
X01AAF (PI) = 3.1415926535897932 X01ABF (GAMMA) = 0.5772156649015329
The basic parameters of the model
X02BHF = 2 X02BJF = 53 X02BKF = -1021 X02BLF = 1024 X02DJF = .TRUE.Derived parameters of the floating-point arithmetic
X02AJF = Z'3CA0000000000001' ( 1.11022302462516D-16 ) X02AKF = Z'0010000000000000' ( 2.22507385850721D-308 ) X02ALF = Z'7FEFFFFFFFFFFFFF' ( 1.79769313486231D+308 ) X02AMF = Z'0010000000000000' ( 2.22507385850721D-308 ) X02ANF = Z'0020000000000000' ( 4.45014771701441D-308 )Parameters of other aspects of the computing environment
X02AHF = Z'4300000000000000' ( 5.62949953421312D+14 ) X02BBF = 2147483647 X02BEF = 15 X02DAF = .FALSE.
It is not possible to use the X04ACF routine with the f90 compiler. Alternative source (x04acft_f90.f) is available with this release.
On-line documentation is bundled with this implementation. Please see the Readme file on the distribution medium for further information.
The NAG Response Centres are available for general enquiries from all users and also for technical queries from sites with an annually licensed product or support service.
The Response Centres are open during office hours, but contact is possible by fax, email and phone (answering machine) at all times.
When contacting a Response Centre please quote your NAG site reference and NAG product code (in this case FLSG619DA).
The NAG websites are an information service providing items of interest to users and prospective users of NAG products and services. The information is reviewed and updated regularly and includes implementation availability, descriptions of products, downloadable software, product documentation and technical reports. The NAG websites can be accessed at
or
http://www.nag.com/ (in North America)
or
http://www.nag-j.co.jp/ (in Japan)
NAG Ltd Wilkinson House Jordan Hill Road OXFORD OX2 8DR NAG Ltd Response Centre United Kingdom email: support@nag.co.uk Tel: +44 (0)1865 511245 Tel: +44 (0)1865 311744 Fax: +44 (0)1865 310139 Fax: +44 (0)1865 310139 Nihon NAG KK Yaesu Nagaoka Building No. 6 1-9-8 Minato Chuo-ku Tokyo Japan email: help@nag-j.co.jp Tel: +81 (0)3 5542 6311 Fax: +81 (0)3 5542 6312 [NP3441/UN - License Managed]