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1281 lines
42 KiB
Groff
1281 lines
42 KiB
Groff
.\" $Header: /upc/share/CVS/netcdf-3/ncgen/ncgen.1,v 1.10 2010/04/29 16:38:55 dmh Exp $
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.TH NCGEN 1 "$Date: 2010/04/29 16:38:55 $" "Printed: \n(yr-\n(mo-\n(dy" "UNIDATA UTILITIES"
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.SH NAME
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ncgen \- From a CDL file generate a netCDF-3 file, a netCDF-4 file or a C program
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.SH SYNOPSIS
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.HP
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ncgen
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.nh
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\%[\-\fIformat_code\fP]
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\%[\-1|3|4|5|6|7]
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\%[\-b]
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\%[\-B \fIbuffersize\fP]
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\%[\-c]
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\%[\-d]
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\%[\-D \fIdebuglevel\fP]
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\%[\-f]
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\%[\-h]
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\%[\-H]
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\%[\-k \fIformat_name\fP]
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\%[\-l \fIb|c|f77|java\fP]
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\%[\-L \fIloglevel\fP]
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\%[\-M \fIname\fP]
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\%[\-n]
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\%[\-N \fIdatasetname\fP]
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\%[\-o \fInetcdf_filename\fP]
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\%[\-P]
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\%[\-x]
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.hy
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.ft
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.SH DESCRIPTION
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\fBncgen\fP generates either a netCDF-3 (i.e. classic) binary .nc file,
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a netCDF-4 (i.e. enhanced) binary .nc file
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or a file in some source language that when executed will
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construct the corresponding binary .nc file.
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The input to \fBncgen\fP is a description of a netCDF
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file in a small language known as CDL (network Common Data form Language),
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described below. Input is read from standard input if no input_file
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is specified.
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If no options are specified in invoking \fBncgen\fP, it merely checks the
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syntax of the input CDL file, producing error messages for
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any violations of CDL syntax. Other options can be used, for example,
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to create the corresponding netCDF file,
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or to generate a C program that uses the netCDF C
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interface to create the netCDF file.
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.LP
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Note that this version of ncgen was originally called ncgen4.
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The older ncgen program has been renamed to ncgen3.
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.LP
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\fBncgen\fP may be used with the companion program \fBncdump\fP to perform
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some simple operations on netCDF files. For example, to rename a dimension
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in a netCDF file, use \fBncdump\fP to get a CDL version of the netCDF file,
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edit the CDL file to change the name of the dimensions, and use \fBncgen\fP
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to generate the corresponding netCDF file from the edited CDL file.
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.SH OPTIONS
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.IP "\fB-1|3|4|5|6|7\fP"
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Alternate method to specify the format.
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.RS
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.RS
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.IP "3 => netcdf classic format"
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.IP "4 => netCDF-4 format (enhanced data model)"
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.IP "5 => netcdf 5 format"
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.IP "6 => netCDF 64-bit format"
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.IP "7 => netCDF-4 classic model format (3+4 == 7)"
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.RE
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.RE
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See the \fB-k\fP flag.
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.IP "\fB-b\fP"
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Create a (binary) netCDF file. If the \fB-o\fP option is absent, a
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default file name will be constructed from the basename of the CDL
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file, with any suffix replaced by the `.nc' extension. If a
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file already exists with the specified name, it will be overwritten.
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.IP "\fB-B\fP \fRbuffersize\fP\fP"
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Specify the internal iterator buffer size.
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.IP "\fB-c\fP"
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Generate
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.B C
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source code that will create a netCDF file
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matching the netCDF specification. The C source code is written to
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standard output; equivalent to \-lc.
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.IP "\fB-d\fP"
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Same as \fB-D1\fP.
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.IP "\fB-D\fP \fRdebuglevel\fP"
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Set the level of debug output.
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.IP "\fB-f\fP"
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Generate
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.B FORTRAN 77
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source code that will create a netCDF file
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matching the netCDF specification.
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The source code is written to
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standard output; equivalent to \-lf77.
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.IP "\fB-h\fP"
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Output help information.
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.IP "\fB-H\fP"
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Output the header only; ignore the \fIdata\fP section.
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.IP "\fB-k \fIformat_name\fP"
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.IP "\fB-\fIformat_code\fP"
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The \-k flag specifies the format of the file to be created and, by inference,
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the data model accepted by ncgen (i.e. netcdf-3 (classic) versus
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netcdf-4 vs netcdf-5). As a shortcut, a numeric \fIformat_code\fP may be specified instead.
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The possible \fIformat_name\fP values for the \-k option are:
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.RS
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.RS
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.IP "'classic' or 'nc3' => netCDF classic format"
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.IP "'64-bit offset' or 'nc6' => netCDF 64-bit format"
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.IP "'64-bit data or 'nc5' => netCDF-5 (64-bit data) format"
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.IP "'netCDF-4' 0r 'nc4' => netCDF-4 format (enhanced data model)"
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.IP "'netCDF-4 classic model' or 'nc7' => netCDF-4 classic model format"
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.RE
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.RE
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Accepted \fIformat_number\fP arguments, just shortcuts for format_names, are:
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.RS
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.RS
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.IP "3 => netcdf classic format"
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.IP "5 => netcdf 5 format"
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.IP "6 => netCDF 64-bit format"
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.IP "4 => netCDF-4 format (enhanced data model)"
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.IP "7 => netCDF-4 classic model format"
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.RE
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.RE
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The numeric code "7" is used because "7=3+4", a mnemonic for the format
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that uses the netCDF-3 data model for compatibility with the netCDF-4
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storage format for performance. Credit is due to NCO for use of these
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numeric codes instead of the old and confusing format numbers.
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.LP
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Note: The old version format numbers '1', '2', '3', '4', equivalent
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to the format names 'nc3', 'nc6', 'nc4', or 'nc7' respectively, are
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also still accepted but deprecated, due to easy confusion between
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format numbers and format names. Various old format name aliases are
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also accepted but deprecated, e.g. 'hdf5', 'enhanced-nc3', etc.
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Also, note that \-v is accepted to mean the same thing as
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\-k for backward compatibility.
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.IP "\fB-l\fP \fRb|c|f77|java\fP"
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The \-l flag specifies the output language to use
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when generating source code that will create or define a netCDF file
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matching the netCDF specification.
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The output is written to standard output.
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The currently supported languages have the following flags.
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.RS
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.RS
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.IP "c|C' => C language output."
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.IP "f77|fortran77' => FORTRAN 77 language output"
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; note that currently only the classic model is supported.
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.IP "j|java' => (experimental) Java language output"
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; targets the existing Unidata Java interface, which means that
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only the classic model is supported.
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.RE
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.RE
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.SH Choosing the output format
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The choice of output format is determined by three flags.
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.IP "\fB-k flag.\fP"
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.IP "\fB_Format attribute (see below).\fP"
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.IP "\fBOccurrence of CDF-5 (64-bit data) or
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netcdf-4 constructs in the input CDL.\fP"
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The term "netCDF-4 constructs" means
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constructs from the enhanced data model,
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not just special performance-related attributes such as
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_ChunkSizes, _DeflateLevel, _Endianness, etc.
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The term "CDF-5 constructs" means
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extended unsigned integer types allowed in the 64-bit data model.
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.LP
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Note that there is an ambiguity between the netCDF-4 case
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and the CDF-5 case is only an unsigned type is seen in the input.
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.LP
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The rules are as follows, in order of application.
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.IP "\fB1.\fP"
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If either Fortran or Java output is specified,
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then \-k flag value of 1 (classic model) will be used.
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Conflicts with the use of enhanced constructs
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in the CDL will report an error.
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.IP "\fB2.\fP"
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If both the \-k flag and _Format attribute are specified,
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the _Format flag will be ignored.
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If no \-k flag is specified, and a _Format attribute value
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is specified, then the \-k flag value
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will be set to that of the _Format attribute.
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Otherwise the \-k flag is undefined.
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.IP "\fB3.\fP"
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If the \-k option is defined and is consistent with the CDL,
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ncgen will output a file in the requested form,
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else an error will be reported.
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.IP "\fB4.\fP"
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If the \-k flag is undefined,
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and if there are CDF-5 constructs, only, in the CDL,
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a \-k flag value of 5 (64-bit data model) will be used.
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If there are true netCDF-4 constructs in the CDL,
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a \-k flag value of 3 (enhanced model) will be used.
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.IP "\fB5.\fP"
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If special performance-related attributes are specified in the CDL,
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a \-k flag value of 4 (netCDF-4 classic model) will be used.
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.IP "\fB6.\fP"
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Otherwise ncgen will set the \-k flag to 1 (classic model).
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.RE
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.IP "\fB-L\fP \fRloglevel\fP"
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.IP "\fB-M\fP \fRname\fP"
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Specify the name for the main function for C, F77, or Java.
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.IP "\fB-n\fP"
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.IP "\fB-N\fP \fRdatasetname\fP"
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.IP "\fB-o\fP \fRnetcdf_file\fP"
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Name of the file to pass to calls to "nc_create()".
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If this option is specified it implies
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(in the absence of any explicit \-l flag) the "\fB-b\fP" option.
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This option is necessary because netCDF files
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cannot be written directly to standard output, since standard output is not
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seekable.
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.IP "\fB-P\fP"
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Use NC_DISKLESS mode to create the file totally in memory
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before persisting it to disk.
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.IP "\fB-x\fP"
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Don't initialize data with fill values. This can speed up creation of
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large netCDF files greatly, but later attempts to read unwritten data
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from the generated file will not be easily detectable.
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.SH EXAMPLES
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.LP
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Check the syntax of the CDL file `\fBfoo.cdl\fP':
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.RS
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.HP
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ncgen foo.cdl
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.RE
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.LP
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From the CDL file `\fBfoo.cdl\fP', generate an equivalent binary netCDF file
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named `\fBx.nc\fP':
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.RS
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.HP
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ncgen \-o x.nc foo.cdl
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.RE
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.LP
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From the CDL file `\fBfoo.cdl\fP', generate a C program containing the
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netCDF function invocations necessary to create an equivalent binary netCDF
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file named `\fBx.nc\fP':
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.RS
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.HP
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ncgen \-lc foo.cdl >x.c
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.RE
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.LP
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.SH USAGE
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.SS "CDL Syntax Overview"
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.LP
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Below is an example of CDL syntax, describing a netCDF file with several
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named dimensions (lat, lon, and time), variables (Z, t, p, rh, lat, lon,
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time), variable attributes (units, long_name, valid_range, _FillValue),
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and some data. CDL keywords are in boldface. (This example is intended to
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illustrate the syntax; a real CDL file would have a more complete set of
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attributes so that the data would be more completely self-describing.)
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.RS
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.nf
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netcdf foo { // an example netCDF specification in CDL
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\fBtypes\fP:
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\fIubyte\fP \fIenum\fP enum_t {Clear = 0, Cumulonimbus = 1, Stratus = 2};
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\fIopaque\fP(11) opaque_t;
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\fIint\fP(*) vlen_t;
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\fBdimensions\fP:
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lat = 10, lon = 5, time = \fIunlimited\fP ;
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\fBvariables\fP:
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\fIlong\fP lat(lat), lon(lon), time(time);
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\fIfloat\fP Z(time,lat,lon), t(time,lat,lon);
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\fIdouble\fP p(time,lat,lon);
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\fIlong\fP rh(time,lat,lon);
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\fIstring\fP country(time,lat,lon);
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\fIubyte\fP tag;
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// variable attributes
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lat:long_name = "latitude";
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lat:units = "degrees_north";
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lon:long_name = "longitude";
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lon:units = "degrees_east";
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time:units = "seconds since 1992-1-1 00:00:00";
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// typed variable attributes
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\fIstring\fP Z:units = "geopotential meters";
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\fIfloat\fP Z:valid_range = 0., 5000.;
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\fIdouble\fP p:_FillValue = \-9999.;
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\fIlong\fP rh:_FillValue = \-1;
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\fIvlen_t\fP :globalatt = {17, 18, 19};
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\fBdata\fP:
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lat = 0, 10, 20, 30, 40, 50, 60, 70, 80, 90;
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lon = \-140, \-118, \-96, \-84, \-52;
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\fBgroup\fP: g {
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\fBtypes\fP:
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\fIcompound\fP cmpd_t { \fIvlen_t\fP f1; \fIenum_t\fP f2;};
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} // group g
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\fBgroup\fP: h {
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\fBvariables\fP:
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/g/\fIcmpd_t\fP compoundvar;
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\fBdata\fP:
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compoundvar = { {3,4,5}, enum_t.Stratus } ;
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} // group h
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}
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.fi
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.RE
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.LP
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All CDL statements are terminated by a semicolon. Spaces, tabs,
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and newlines can be used freely for readability.
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Comments may follow the characters `//' on any line.
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.LP
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A CDL description consists of five optional parts:
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\fItypes\fP,
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\fIdimensions\fP,
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\fIvariables\fP,
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\fIdata\fP,
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beginning with the keyword
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.BR `types:' ,
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.BR `dimensions:' ,
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.BR `variables:' ,
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and
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.BR `data:',
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respectively.
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Note several things:
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(1) the keyword includes the trailing colon, so there must not be any space before the colon character,
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and (2) the keywords are required to be lower case.
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.LP
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The \fBvariables:\fP section may contain \fIvariable declarations\fP
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and \fIattribute assignments\fP.
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All sections may contain global attribute assignments.
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.LP
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In addition, after the \fBdata:\fP section, the user
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may define a series of groups (see the example above).
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Groups themselves can contain types, dimensions, variables,
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data, and other (nested) groups.
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.LP
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The netCDF \fBtypes:\fP section declares the user defined types.
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These may be constructed using any of the following types:
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\fBenum\fP, \fBvlen\fP, \fBopaque\fP, or \fBcompound\fP.
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.LP
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A netCDF \fIdimension\fP is used to define the shape of one or more of the
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multidimensional variables contained in the netCDF file. A netCDF
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dimension has a name and a size. A dimension
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can have the \fBunlimited\fP size, which means a variable using this
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dimension can grow to any length in that dimension.
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.LP
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A \fIvariable\fP represents a multidimensional array of values of the
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same type. A variable has a name, a data type, and a shape described
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by its list of dimensions. Each variable may also have associated
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\fIattributes\fP (see below) as well as data values. The name, data
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type, and shape of a variable are specified by its declaration in the
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\fIvariable\fP section of a CDL description. A variable may have the same
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name as a dimension; by convention such a variable is one-dimensional
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and contains coordinates of the dimension it names. Dimensions need
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not have corresponding variables.
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.LP
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|
A netCDF \fIattribute\fP contains information about a netCDF variable or
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about the whole netCDF dataset. Attributes are used
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to specify such properties as units, special values, maximum and
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minimum valid values, scaling factors, offsets, and parameters. Attribute
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information is represented by single values or arrays of values. For
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example, "units" is an attribute represented by a character array such
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as "celsius". An attribute has an associated variable, a name,
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a data type, a length, and a value. In contrast to variables that are
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intended for data, attributes are intended for metadata (data about
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data).
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Unlike netCDF-3, attribute types can be any user defined type
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as well as the usual built-in types.
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.LP
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In CDL, an attribute is designated by a
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a type, a variable, a ':', and then an attribute name.
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The type is optional and if missing, it will be inferred from the values
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assigned to the attribute.
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|
It is possible to assign \fIglobal\fP attributes
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not associated with any variable to the netCDF as a whole by omitting
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the variable name in the attribute declaration.
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Notice that there is a potential ambiguity in a specification such as
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.nf
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x : a = ...
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.fi
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In this situation, x could be either a type for a global attribute,
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or the variable name for an attribute. Since there could both be a type named
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x and a variable named x, there is an ambiguity.
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The rule is that in this situation, x will be interpreted as a
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type if possible, and otherwise as a variable.
|
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.LP
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|
If not specified, the data type of an attribute in CDL
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|
is derived from the type of the value(s) assigned to it. The length of
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an attribute is the number of data values assigned to it, or the
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|
number of characters in the character string assigned to it. Multiple
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values are assigned to non-character attributes by separating the
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values with commas. All values assigned to an attribute must be of
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the same type.
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.LP
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|
The names for CDL dimensions, variables, attributes, types, and groups
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|
may contain any non-control utf-8 character
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|
except the forward slash character (`/').
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|
However, certain characters must escaped if they are used in a name,
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|
where the escape character is the backward slash `\\'.
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|
In particular, if the leading character off the name is a digit (0-9),
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|
then it must be preceded by the escape character.
|
|
In addition, the characters ` !"#$%&()*,:;<=>?[]^`\'{}|~\\'
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|
must be escaped if they occur anywhere in a name.
|
|
Note also that attribute names that begin with an underscore (`_')
|
|
are reserved for the use of Unidata and should not be used in user
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|
defined attributes.
|
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.LP
|
|
Note also that the words
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`variables',
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`dimensions',
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`data',
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`group',
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and `types'
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are legal CDL names, but be careful that there is a space
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between them and any following colon character when used as a variable name.
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|
This is mostly an issue with attribute declarations.
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|
For example, consider this.
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|
.HP
|
|
.RS
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|
.nf
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netcdf ... {
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|
...
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variables:
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int dimensions;
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dimensions: attribute=0 ; // this will cause an error
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|
dimensions : attribute=0 ; // this is ok.
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|
...
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}
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.fi
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.RE
|
|
.LP
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|
The optional \fBdata:\fP section of a CDL specification is where
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|
netCDF variables may be initialized. The syntax of an initialization
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|
is simple: a variable name, an equals sign, and a
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|
comma-delimited list of constants (possibly separated by spaces, tabs
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|
and newlines) terminated with a semicolon. For multi-dimensional
|
|
arrays, the last dimension varies fastest. Thus row-order rather than
|
|
column order is used for matrices. If fewer values are supplied than
|
|
are needed to fill a variable, it is extended with a type-dependent
|
|
`fill value', which can be overridden by supplying a value for a
|
|
distinguished variable attribute named `_FillValue'. The
|
|
types of constants need not match the type declared for a variable;
|
|
coercions are done to convert integers to floating point, for example.
|
|
The constant `_' can be used to designate the fill value for a variable.
|
|
If the type of the variable is explicitly `string', then the special
|
|
constant `NIL` can be used to represent a nil string, which is not the
|
|
same as a zero length string.
|
|
.SS "Primitive Data Types"
|
|
.LP
|
|
.RS
|
|
.nf
|
|
\fBchar\fP characters
|
|
\fBbyte\fP 8-bit data
|
|
\fBshort\fP 16-bit signed integers
|
|
\fBint\fP 32-bit signed integers
|
|
\fBlong\fP (synonymous with \fBint\fP)
|
|
\fBint64\fP 64-bit signed integers
|
|
\fBfloat\fP IEEE single precision floating point (32 bits)
|
|
\fBreal\fP (synonymous with \fBfloat\fP)
|
|
\fBdouble\fP IEEE double precision floating point (64 bits)
|
|
\fBubyte\fP unsigned 8-bit data
|
|
\fBushort\fP 16-bit unsigned integers
|
|
\fBuint\fP 32-bit unsigned integers
|
|
\fBuint64\fP 64-bit unsigned integers
|
|
\fBstring\fP arbitrary length strings
|
|
.fi
|
|
.RE
|
|
.LP
|
|
CDL supports a superset of the primitive data types of C.
|
|
The names for the primitive data types are reserved words in CDL,
|
|
so the names of variables, dimensions, and attributes must not be
|
|
primitive type names. In declarations, type names may be specified
|
|
in either upper or lower case.
|
|
.LP
|
|
Bytes are intended to hold a full eight
|
|
bits of data, and the zero byte has no special significance, as it
|
|
mays for character data.
|
|
\fBncgen\fP converts \fBbyte\fP declarations to \fBchar\fP
|
|
declarations in the output C code and to the nonstandard \fBBYTE\fP
|
|
declaration in output Fortran code.
|
|
.LP
|
|
Shorts can hold values between \-32768 and 32767.
|
|
\fBncgen\fP converts \fBshort\fP declarations to \fBshort\fP
|
|
declarations in the output C code and to the nonstandard \fBINTEGER*2\fP
|
|
declaration in output Fortran code.
|
|
.LP
|
|
Ints can hold values between \-2147483648 and 2147483647.
|
|
\fBncgen\fP converts \fBint\fP declarations to \fBint\fP
|
|
declarations in the output C code and to \fBINTEGER\fP
|
|
declarations in output Fortran code. \fBlong\fP
|
|
is accepted as a synonym for \fBint\fP in CDL declarations, but is
|
|
deprecated since there are now platforms with 64-bit representations
|
|
for C longs.
|
|
.LP
|
|
Int64 can hold values between \-9223372036854775808
|
|
and 9223372036854775807.
|
|
\fBncgen\fP converts \fBint64\fP declarations to \fBlonglong\fP
|
|
declarations in the output C code.
|
|
.\" and to \fBINTEGER\fP declarations in output Fortran code.
|
|
.LP
|
|
Floats can hold values between about \-3.4+38 and 3.4+38. Their
|
|
external representation is as 32-bit IEEE normalized single-precision
|
|
floating point numbers. \fBncgen\fP converts \fBfloat\fP
|
|
declarations to \fBfloat\fP declarations in the output C code and to
|
|
\fBREAL\fP declarations in output Fortran code. \fBreal\fP is accepted
|
|
as a synonym for \fBfloat\fP in CDL declarations.
|
|
.LP
|
|
Doubles can hold values between about \-1.7+308 and 1.7+308. Their
|
|
external representation is as 64-bit IEEE standard normalized
|
|
double-precision floating point numbers. \fBncgen\fP converts
|
|
\fBdouble\fP declarations to \fBdouble\fP declarations in the output C
|
|
code and to \fBDOUBLE PRECISION\fP declarations in output Fortran
|
|
code.
|
|
.LP
|
|
The unsigned counterparts of the above integer types
|
|
are mapped to the corresponding unsigned C types.
|
|
Their ranges are suitably modified to start at zero.
|
|
.LP
|
|
The technical interpretation of the char type is that it is an unsigned
|
|
8-bit value. The encoding of the 256 possible values
|
|
is unspecified by default. A variable of char type
|
|
may be marked with an "_Encoding" attribute to indicate
|
|
the character set to be used: US-ASCII, ISO-8859-1, etc.
|
|
Note that specifying the encoding of UTF-8 is equivalent to
|
|
specifying US-ASCII
|
|
This is because multi-byte UTF-8 characters cannot
|
|
be stored in an 8-bit character. The only legal
|
|
single byte UTF-8 values are by definition
|
|
the 7-bit US-ASCII encoding with the top bit set to zero.
|
|
.LP
|
|
Strings are assumed by default to be encoded using UTF-8.
|
|
Note that this means that multi-byte UTF-8 encodings may
|
|
be present in the string, so it is possible that the number
|
|
of distinct UTF-8 characters in a string is smaller than
|
|
the number of 8-bit bytes used to store the string.
|
|
.LP
|
|
.SS "CDL Constants"
|
|
.LP
|
|
Constants assigned to attributes or variables may be of any of the
|
|
basic netCDF types. The syntax for constants is similar to C syntax,
|
|
except that type suffixes must be appended to shorts and floats to
|
|
distinguish them from longs and doubles.
|
|
.LP
|
|
A \fIbyte\fP constant is represented by
|
|
an integer constant with a `b' (or
|
|
`B') appended. In the old netCDF-2 API, byte constants could also be
|
|
represented using single characters or standard C character escape
|
|
sequences such as `a' or `\n'. This is still supported for backward
|
|
compatibility, but deprecated to make the distinction clear between
|
|
the numeric byte type and the textual char type. Example byte
|
|
constants include:
|
|
.RS
|
|
.nf
|
|
0b // a zero byte
|
|
\-1b // \-1 as an 8-bit byte
|
|
255b // also \-1 as a signed 8-bit byte
|
|
.fi
|
|
.RE
|
|
.LP
|
|
\fIshort\fP integer constants are intended for representing 16-bit
|
|
signed quantities. The form of a \fIshort\fP constant is an integer
|
|
constant with an `s' or `S' appended. If a \fIshort\fP constant
|
|
begins with `0', it is interpreted as octal, except that if it begins with
|
|
`0x', it is interpreted as a hexadecimal constant. For example:
|
|
.RS
|
|
.nf
|
|
\-2s // a short \-2
|
|
0123s // octal
|
|
0x7ffs //hexadecimal
|
|
.fi
|
|
.RE
|
|
.LP
|
|
\fIint\fP integer constants are intended for representing 32-bit signed
|
|
quantities. The form of an \fIint\fP constant is an ordinary integer
|
|
constant, although it is acceptable to optionally append a single `l' or
|
|
`L' (again, deprecated). Be careful, though, the L suffix is interpreted
|
|
as a 32 bit integer, and never as a 64 bit integer. This can be confusing
|
|
since the C long type can ambigously be either 32 bit or 64 bit.
|
|
.LP
|
|
If an \fIint\fP constant begins with `0', it is interpreted as
|
|
octal, except that if it begins with `0x', it is interpreted as a hexadecimal
|
|
constant (but see opaque constants below).
|
|
Examples of valid \fIint\fP constants include:
|
|
.RS
|
|
.nf
|
|
\-2
|
|
1234567890L
|
|
0123 // octal
|
|
0x7ff // hexadecimal
|
|
.fi
|
|
.RE
|
|
.LP
|
|
\fIint64\fP integer constants are intended for representing 64-bit
|
|
signed quantities. The form of an \fIint64\fP constant is an integer
|
|
constant with an `ll' or `LL' appended. If an \fIint64\fP constant
|
|
begins with `0', it is interpreted as octal, except that if it begins with
|
|
`0x', it is interpreted as a hexadecimal constant. For example:
|
|
.RS
|
|
.nf
|
|
\-2ll // an unsigned \-2
|
|
0123LL // octal
|
|
0x7ffLL //hexadecimal
|
|
.fi
|
|
.RE
|
|
.LP
|
|
Floating point constants of type \fIfloat\fP are appropriate for representing
|
|
floating point data with about seven significant digits of precision.
|
|
The form of a \fIfloat\fP constant is the same as a C floating point
|
|
constant with an `f' or `F' appended. For example the following
|
|
are all acceptable \fIfloat\fP constants:
|
|
.RS
|
|
.nf
|
|
\-2.0f
|
|
3.14159265358979f // will be truncated to less precision
|
|
1.f
|
|
|
|
.fi
|
|
.RE
|
|
.LP
|
|
Floating point constants of type \fIdouble\fP are appropriate for
|
|
representing floating point data with about sixteen significant digits
|
|
of precision. The form of a \fIdouble\fP constant is the same as a C
|
|
floating point constant. An optional `d' or `D' may be appended.
|
|
For example the following are all acceptable \fIdouble\fP constants:
|
|
.RS
|
|
.nf
|
|
\-2.0
|
|
3.141592653589793
|
|
1.0e-20
|
|
1.d
|
|
.fi
|
|
.RE
|
|
.LP
|
|
Unsigned integer constants can be created by appending
|
|
the character 'U' or 'u' between the constant and any trailing
|
|
size specifier, or immediately at the end of the size specifier.
|
|
Thus one could say
|
|
10U, 100su, 100000ul, or 1000000llu, for example.
|
|
.LP
|
|
Single character constants may be enclosed in single quotes.
|
|
If a sequence of one or more characters is enclosed
|
|
in double quotes, then its interpretation must be inferred
|
|
from the context. If the dataset is created using the netCDF
|
|
classic model, then all such constants are interpreted
|
|
as a character array, so each character in the constant
|
|
is interpreted as if it were a single character.
|
|
If the dataset is netCDF extended, then the constant may
|
|
be interpreted as for the classic model or as a true string
|
|
(see below) depending on the type of the attribute or variable
|
|
into which the string is contained.
|
|
.LP
|
|
The interpretation of char constants is that those
|
|
that are in the printable ASCII range (' '..'~') are assumed to
|
|
be encoded as the 1-byte subset ofUTF-8, which is equivalent to US-ASCII.
|
|
In all cases, the usual C string escape conventions are honored
|
|
for values from 0 thru 127. Values greater than 127 are allowed,
|
|
but their encoding is undefined.
|
|
For netCDF extended, the use of the char type is deprecated
|
|
in favor of the string type.
|
|
.LP
|
|
Some character constant examples are as follows.
|
|
.RS
|
|
.nf
|
|
'a' // ASCII `a'
|
|
"a" // equivalent to 'a'
|
|
"Two\\nlines\\n" // a 10-character string with two embedded newlines
|
|
"a bell:\\007" // a string containing an ASCII bell
|
|
.fi
|
|
.RE
|
|
Note that the netCDF character array "a" would fit in a one-element
|
|
variable, since no terminating NULL character is assumed. However, a zero
|
|
byte in a character array is interpreted as the end of the significant
|
|
characters by the \fBncdump\fP program, following the C convention.
|
|
Therefore, a NULL byte should not be embedded in a character string unless
|
|
at the end: use the \fIbyte\fP data type instead for byte arrays that
|
|
contain the zero byte.
|
|
.LP
|
|
\fIString\fP constants are, like character constants,
|
|
represented using double quotes. This represents a potential
|
|
ambiguity since a multi-character string may also indicate
|
|
a dimensioned character value. Disambiguation usually occurs
|
|
by context, but care should be taken to specify the\fIstring\fP
|
|
type to ensure the proper choice.
|
|
String constants are assumed to always be UTF-8 encoded. This
|
|
specifically means that the string constant may actually
|
|
contain multi-byte UTF-8 characters.
|
|
The special constant `NIL` can be used to represent a nil string, which is not the
|
|
same as a zero length string.
|
|
.LP
|
|
\fIOpaque\fP constants are represented as
|
|
sequences of hexadecimal digits preceded by 0X or 0x: 0xaa34ffff,
|
|
for example.
|
|
These constants can still be used as integer constants
|
|
and will be either truncated or extended as necessary.
|
|
.SS "Compound Constant Expressions"
|
|
.LP
|
|
In order to assign values to variables (or attributes)
|
|
whose type is user-defined type, the constant notation has been
|
|
extended to include sequences of constants enclosed in curly
|
|
brackets (e.g. "{"..."}").
|
|
Such a constant is called a compound constant, and compound constants
|
|
can be nested.
|
|
.LP
|
|
Given a type "T(*) vlen_t", where T is some other arbitrary base type,
|
|
constants for this should be specified as follows.
|
|
.nf
|
|
vlen_t var[2] = {t11,t12,...t1N}, {t21,t22,...t2m};
|
|
.fi
|
|
The values tij, are assumed to be constants of type T.
|
|
.LP
|
|
Given a type "compound cmpd_t {T1 f1; T2 f2...Tn fn}",
|
|
where the Ti are other arbitrary base types,
|
|
constants for this should be specified as follows.
|
|
.nf
|
|
cmpd_t var[2] = {t11,t12,...t1N}, {t21,t22,...t2n};
|
|
.fi
|
|
The values tij, are assumed to be constants of type Ti.
|
|
If the fields are missing, then they will be set using any
|
|
specified or default fill value for the field's base type.
|
|
.LP
|
|
The general set of rules for using braces are defined in the
|
|
.B Specifying
|
|
.B Datalists
|
|
section below.
|
|
.LP
|
|
.SS "Scoping Rules"
|
|
.LP
|
|
With the addition of groups, the name space for defined objects
|
|
is no longer flat. References (names)
|
|
of any type, dimension, or variable may be prefixed
|
|
with the absolute path specifying a specific declaration.
|
|
Thus one might say
|
|
.nf
|
|
variables:
|
|
/g1/g2/t1 v1;
|
|
.fi
|
|
The type being referenced (t1) is the one within group g2, which in
|
|
turn is nested in group g1.
|
|
The similarity of this notation to Unix file paths is deliberate,
|
|
and one can consider groups as a form of directory structure.
|
|
.LP
|
|
When name is not prefixed, then scope rules are applied to locate the
|
|
specified declaration. Currently, there are three rules: one for dimensions,
|
|
one for types and enumeration constants, and one for all others.
|
|
.HP
|
|
When an unprefixed name of a dimension is used (as in a
|
|
variable declaration), ncgen first looks in the immediately
|
|
enclosing group for the dimension. If it is not found
|
|
there, then it looks in the group enclosing this group.
|
|
This continues up the group hierarchy until the dimension is
|
|
found, or there are no more groups to search.
|
|
.HP
|
|
2. When an unprefixed name of a type or an enumeration constant
|
|
is used, ncgen searches the group tree using a pre-order depth-first
|
|
search. This essentially means that it will find the matching declaration
|
|
that precedes the reference textually in the cdl file and that
|
|
is "highest" in the group hierarchy.
|
|
.HP
|
|
3. For all other names, only the immediately enclosing group is searched.
|
|
.LP
|
|
One final note. Forward references are not allowed.
|
|
This means that specifying, for example,
|
|
/g1/g2/t1 will fail if this reference occurs before g1 and/or g2 are defined.
|
|
.SS "Specifying Enumeration Constants"
|
|
.LP
|
|
References to Enumeration constants (in data lists) can be ambiguous
|
|
since the same enumeration constant name can be defined in more than
|
|
one enumeration. If a cdl file specified an ambiguous constant,
|
|
then ncgen will signal an error. Such constants can be disambiguated
|
|
in two ways.
|
|
.IP "\fB1.\fP"
|
|
Prefix the enumeration constant with the name of the enumeration separated
|
|
by a dot: \fIenum.econst\fP, for example.
|
|
.IP "\fB2.\fP"
|
|
If case one is not sufficient to disambiguate the enumeration constant,
|
|
then one must specify the precise enumeration type using
|
|
a group path: \fI/g1/g2/enum.econst\fP, for example.
|
|
.SS "Special Attributes"
|
|
.LP
|
|
Special, virtual, attributes can be specified to provide
|
|
performance-related information about the file format and
|
|
about variable properties.
|
|
The file must be a netCDF-4 file for these to take effect.
|
|
.LP
|
|
These special virtual attributes are not actually part of the file,
|
|
they are merely a convenient way to set miscellaneous
|
|
properties of the data in CDL
|
|
.LP
|
|
The special attributes currently supported are as follows:
|
|
`_Format',
|
|
`_Fletcher32,
|
|
`_ChunkSizes',
|
|
`_Endianness',
|
|
`_DeflateLevel',
|
|
`_Shuffle', and
|
|
`_Storage'.
|
|
.LP
|
|
`_Format' is a global attribute specifying the netCDF format
|
|
variant. Its value must be a single string
|
|
matching one of `classic', `64-bit offset', `64-bit data', `netCDF-4', or
|
|
`netCDF-4 classic model'.
|
|
.LP
|
|
The rest of the special attributes are all variable attributes.
|
|
Essentially all of then map to some corresponding `nc_def_var_XXX'
|
|
function as defined in the netCDF-4 API.
|
|
For the attributes that are essentially boolean (_Fletcher32, _Shuffle,
|
|
and _NOFILL), the value true can be specified by using the strings
|
|
`true' or `1', or by using the integer 1.
|
|
The value false expects either `false', `0', or the integer 0.
|
|
The actions associated with these attributes are as follows.
|
|
.IP 1. 3
|
|
`_Fletcher32 sets the `fletcher32' property for a variable.
|
|
.IP 2. 3
|
|
`_Endianness' is either `little' or `big', depending on
|
|
how the variable is stored when first written.
|
|
.IP 3. 3
|
|
`_DeflateLevel' is an
|
|
integer between 0 and 9 inclusive if compression has been specified
|
|
for the variable.
|
|
.IP 4. 3
|
|
`_Shuffle' specifies if the the shuffle filter should be used.
|
|
.IP 5. 3
|
|
`_Storage' is `contiguous' or `compact` or `chunked'.
|
|
.IP 6. 3
|
|
`_ChunkSizes' is a list of chunk sizes for each dimension of
|
|
the variable
|
|
.LP
|
|
Note that attributes such as "add_offset" or "scale_factor"
|
|
have no special meaning to ncgen. These attributes are
|
|
currently conventions, handled above the library layer by
|
|
other utility packages, for example NCO.
|
|
.LP
|
|
.SS "Specifying Datalists"
|
|
.LP
|
|
Specifying datalists for variables in the `data:` section can be somewhat
|
|
complicated. There are some rules that must be followed
|
|
to ensure that datalists are parsed correctly by ncgen.
|
|
.LP
|
|
First, the top level is automatically assumed to be a list of items, so it should not be inside {...}.
|
|
That means that if the variable is a scalar, there will be a single top-level element
|
|
and if the variable is an array, there will be N top-level elements.
|
|
For each element of the top level list, the following rules should be applied.
|
|
.IP 1. 3
|
|
Instances of UNLIMITED dimensions (other than the first dimension) must be surrounded by {...} in order to specify the size.
|
|
.IP 2. 3
|
|
Compound instances must be embedded in {...}
|
|
.IP 3. 3
|
|
Non-scalar fields of compound instances must be embedded in {...}.
|
|
.IP 4. 3
|
|
Instances of vlens must be surrounded by {...} in order to specify the size.
|
|
.LP
|
|
Datalists associated with attributes are implicitly a vector (i.e., a list) of values of the type of the attribute and the above rules must apply with that in mind.
|
|
.IP 7. 3
|
|
No other use of braces is allowed.
|
|
.LP
|
|
Note that one consequence of these rules is that
|
|
arrays of values cannot have subarrays within braces.
|
|
Consider, for example, int var(d1)(d2)...(dn),
|
|
where none of d2...dn are unlimited.
|
|
A datalist for this variable must be a single list of integers,
|
|
where the number of integers is no more than D=d1*d2*...dn values;
|
|
note that the list can be less than D, in which case fill values
|
|
will be used to pad the list.
|
|
.LP
|
|
Rule 6 about attribute datalist has the following consequence.
|
|
If the type of the attribute is a compound (or vlen) type, and if
|
|
the number of entries in the list is one, then the compound instances
|
|
must be enclosed in braces.
|
|
.LP
|
|
.SS "Specifying Character Datalists"
|
|
.LP
|
|
Specifying datalists for variables of type char also has some
|
|
complications. consider, for example
|
|
.RS
|
|
.nf
|
|
dimensions: u=UNLIMITED; d1=1; d2=2; d3=3;
|
|
d4=4; d5=5; u2=UNLIMITED;
|
|
variables: char var(d4,d5);
|
|
datalist: var="1", "two", "three";
|
|
.fi
|
|
.RE
|
|
.LP
|
|
We have twenty elements of var to fill (d5 X d4)
|
|
and we have three strings of length 1, 3, 5.
|
|
How do we assign the characters in the strings to the
|
|
twenty elements?
|
|
.LP
|
|
This is challenging because it is desirable to mimic
|
|
the original ncgen (ncgen3).
|
|
The core algorithm is notionally as follows.
|
|
.IP 1. 3
|
|
Assume we have a set of dimensions D1..Dn,
|
|
where D1 may optionally be an Unlimited dimension.
|
|
It is assumed that the sizes of the Di are all known
|
|
(including unlimited dimensions).
|
|
.IP 2. 3
|
|
Given a sequence of string or character constants
|
|
C1..Cm, our goal is to construct a single string
|
|
whose length is the cross product of D1 thru Dn.
|
|
Note that for purposes of this algorithm, character constants
|
|
are treated as strings of size 1.
|
|
.IP 3. 3
|
|
Construct Dx = cross product of D1 thru D(n-1).
|
|
.IP 4. 3
|
|
For each constant Ci, add fill characters as needed
|
|
so that its length is a multiple of Dn.
|
|
.IP 5. 3
|
|
Concatenate the modified C1..Cm to produce string S.
|
|
.IP 6. 3
|
|
Add fill characters to S to make its length be a multiple of Dn.
|
|
.IP 8. 3
|
|
If S is longer than the Dx * Dn, then truncate
|
|
and generate a warning.
|
|
.LP
|
|
There are three other cases of note.
|
|
.IP 1. 3
|
|
If there is only a single, unlimited dimension,
|
|
then all of the constants are concatenated
|
|
and fill characters are added to the
|
|
end of the resulting string to make its
|
|
length be that of the unlimited dimension.
|
|
If the length is larger than
|
|
the unlimited dimension, then it is truncated
|
|
with a warning.
|
|
.IP 2. 3
|
|
For the case of character typed vlen, "char(*) vlen_t" for example.
|
|
we simply concatenate all the constants with no filling at all.
|
|
.IP 3. 3
|
|
For the case of a character typed attribute,
|
|
we simply concatenate all the constants.
|
|
.LP
|
|
In netcdf-4, dimensions other than the first can be unlimited.
|
|
Of course by the rules above, the interior unlimited instances
|
|
must be delimited by {...}. For example.
|
|
.in +5
|
|
.nf
|
|
variables: char var(u,u2);
|
|
datalist: var={"1", "two"}, {"three"};
|
|
.fi
|
|
.in -5
|
|
In this case u will have the effective length of two.
|
|
Within each instance of u2, the rules above will apply, leading
|
|
to this.
|
|
.in +5
|
|
datalist: var={"1","t","w","o"}, {"t","h","r","e","e"};
|
|
.in -5
|
|
The effective size of u2 will be the max of the two instance lengths
|
|
(five in this case)
|
|
and the shorter will be padded to produce this.
|
|
.in +5
|
|
datalist: var={"1","t","w","o","\\0"}, {"t","h","r","e","e"};
|
|
.in -5
|
|
.LP
|
|
Consider an even more complicated case.
|
|
.in +5
|
|
.nf
|
|
variables: char var(u,u2,u3);
|
|
datalist: var={{"1", "two"}}, {{"three"},{"four","xy"}};
|
|
.fi
|
|
.in -5
|
|
In this case u again will have the effective length of two.
|
|
The u2 dimensions will have a size = max(1,2) = 2;
|
|
Within each instance of u2, the rules above will apply, leading to this.
|
|
.in +5
|
|
.nf
|
|
datalist: var={{"1","t","w","o"}}, {{"t","h","r","e","e"},{"f","o","u","r","x","y"}};
|
|
.fi
|
|
.in -5
|
|
The effective size of u3 will be the max of the two instance lengths
|
|
(six in this case) and the shorter ones will be padded to produce this.
|
|
.in +5
|
|
.nf
|
|
datalist: var={{"1","t","w","o","\0","\0"}}, {{"t","h","r","e","e","\0"},{"f","o","u","r","x","y"}};
|
|
.fi
|
|
.in -5
|
|
Note however that the first instance of u2 is less than the max length
|
|
of u2, so we need to add a filler for another instance of u2, producing this.
|
|
.in +5
|
|
.nf
|
|
datalist: var={{"1","t","w","o","\0","\0"},{"\0","\0","\0","\0","\0","\0"}}, {{"t","h","r","e","e","\0"},{"f","o","u","r","x","y"}};
|
|
.fi
|
|
.in -5
|
|
|
|
.SH BUGS
|
|
.LP
|
|
The programs generated by \fBncgen\fP when using the \fB-c\fP flag
|
|
use initialization statements to store data in variables, and will fail to
|
|
produce compilable programs if you try to use them for large datasets, since
|
|
the resulting statements may exceed the line length or number of
|
|
continuation statements permitted by the compiler.
|
|
.LP
|
|
The CDL syntax makes it easy to assign what looks like an array of
|
|
variable-length strings to a netCDF variable, but the strings may simply be
|
|
concatenated into a single array of characters.
|
|
Specific use of the \fIstring\fP type specifier may solve the problem
|
|
|
|
.SH "CDL Grammar"
|
|
.LP
|
|
The file ncgen.y is the definitive grammar for CDL, but a stripped
|
|
down version is included here for completeness.
|
|
.RS
|
|
.nf
|
|
ncdesc: NETCDF
|
|
datasetid
|
|
rootgroup
|
|
;
|
|
|
|
datasetid: DATASETID
|
|
|
|
rootgroup: '{'
|
|
groupbody
|
|
subgrouplist
|
|
'}';
|
|
|
|
groupbody:
|
|
attrdecllist
|
|
typesection
|
|
dimsection
|
|
vasection
|
|
datasection
|
|
;
|
|
|
|
subgrouplist:
|
|
/*empty*/
|
|
| subgrouplist namedgroup
|
|
;
|
|
|
|
namedgroup: GROUP ident '{'
|
|
groupbody
|
|
subgrouplist
|
|
'}'
|
|
attrdecllist
|
|
;
|
|
|
|
typesection: /* empty */
|
|
| TYPES
|
|
| TYPES typedecls
|
|
;
|
|
|
|
typedecls:
|
|
type_or_attr_decl
|
|
| typedecls type_or_attr_decl
|
|
;
|
|
|
|
typename: ident ;
|
|
|
|
type_or_attr_decl:
|
|
typedecl
|
|
| attrdecl ';'
|
|
;
|
|
|
|
typedecl:
|
|
enumdecl optsemicolon
|
|
| compounddecl optsemicolon
|
|
| vlendecl optsemicolon
|
|
| opaquedecl optsemicolon
|
|
;
|
|
|
|
optsemicolon:
|
|
/*empty*/
|
|
| ';'
|
|
;
|
|
|
|
enumdecl: primtype ENUM typename ;
|
|
|
|
enumidlist: enumid
|
|
| enumidlist ',' enumid
|
|
;
|
|
|
|
enumid: ident '=' constint ;
|
|
|
|
opaquedecl: OPAQUE '(' INT_CONST ')' typename ;
|
|
|
|
vlendecl: typeref '(' '*' ')' typename ;
|
|
|
|
compounddecl: COMPOUND typename '{' fields '}' ;
|
|
|
|
fields: field ';'
|
|
| fields field ';'
|
|
;
|
|
|
|
field: typeref fieldlist ;
|
|
|
|
primtype: CHAR_K
|
|
| BYTE_K
|
|
| SHORT_K
|
|
| INT_K
|
|
| FLOAT_K
|
|
| DOUBLE_K
|
|
| UBYTE_K
|
|
| USHORT_K
|
|
| UINT_K
|
|
| INT64_K
|
|
| UINT64_K
|
|
;
|
|
|
|
dimsection: /* empty */
|
|
| DIMENSIONS
|
|
| DIMENSIONS dimdecls
|
|
;
|
|
|
|
dimdecls: dim_or_attr_decl ';'
|
|
| dimdecls dim_or_attr_decl ';'
|
|
;
|
|
|
|
dim_or_attr_decl: dimdeclist | attrdecl ;
|
|
|
|
dimdeclist: dimdecl
|
|
| dimdeclist ',' dimdecl
|
|
;
|
|
|
|
dimdecl:
|
|
dimd '=' UINT_CONST
|
|
| dimd '=' INT_CONST
|
|
| dimd '=' DOUBLE_CONST
|
|
| dimd '=' NC_UNLIMITED_K
|
|
;
|
|
|
|
dimd: ident ;
|
|
|
|
vasection: /* empty */
|
|
| VARIABLES
|
|
| VARIABLES vadecls
|
|
;
|
|
|
|
vadecls: vadecl_or_attr ';'
|
|
| vadecls vadecl_or_attr ';'
|
|
;
|
|
|
|
vadecl_or_attr: vardecl | attrdecl ;
|
|
|
|
vardecl: typeref varlist ;
|
|
|
|
varlist: varspec
|
|
| varlist ',' varspec
|
|
;
|
|
|
|
varspec: ident dimspec ;
|
|
|
|
dimspec: /* empty */
|
|
| '(' dimlist ')'
|
|
;
|
|
|
|
dimlist: dimref
|
|
| dimlist ',' dimref
|
|
;
|
|
|
|
dimref: path ;
|
|
|
|
fieldlist:
|
|
fieldspec
|
|
| fieldlist ',' fieldspec
|
|
;
|
|
|
|
fieldspec: ident fielddimspec ;
|
|
|
|
fielddimspec: /* empty */
|
|
| '(' fielddimlist ')'
|
|
;
|
|
|
|
fielddimlist:
|
|
fielddim
|
|
| fielddimlist ',' fielddim
|
|
;
|
|
|
|
fielddim:
|
|
UINT_CONST
|
|
| INT_CONST
|
|
;
|
|
|
|
/* Use this when referencing defined objects */
|
|
varref: type_var_ref ;
|
|
|
|
typeref: type_var_ref ;
|
|
|
|
type_var_ref:
|
|
path
|
|
| primtype
|
|
;
|
|
|
|
/* Use this for all attribute decls */
|
|
/* Watch out; this is left recursive */
|
|
attrdecllist: /*empty*/ | attrdecl ';' attrdecllist ;
|
|
|
|
attrdecl:
|
|
':' ident '=' datalist
|
|
| typeref type_var_ref ':' ident '=' datalist
|
|
| type_var_ref ':' ident '=' datalist
|
|
| type_var_ref ':' _FILLVALUE '=' datalist
|
|
| typeref type_var_ref ':' _FILLVALUE '=' datalist
|
|
| type_var_ref ':' _STORAGE '=' conststring
|
|
| type_var_ref ':' _CHUNKSIZES '=' intlist
|
|
| type_var_ref ':' _FLETCHER32 '=' constbool
|
|
| type_var_ref ':' _DEFLATELEVEL '=' constint
|
|
| type_var_ref ':' _SHUFFLE '=' constbool
|
|
| type_var_ref ':' _ENDIANNESS '=' conststring
|
|
| type_var_ref ':' _NOFILL '=' constbool
|
|
| ':' _FORMAT '=' conststring
|
|
;
|
|
|
|
path:
|
|
ident
|
|
| PATH
|
|
;
|
|
|
|
datasection: /* empty */
|
|
| DATA
|
|
| DATA datadecls
|
|
;
|
|
|
|
datadecls:
|
|
datadecl ';'
|
|
| datadecls datadecl ';'
|
|
;
|
|
|
|
datadecl: varref '=' datalist ;
|
|
datalist:
|
|
datalist0
|
|
| datalist1
|
|
;
|
|
|
|
datalist0:
|
|
/*empty*/
|
|
;
|
|
|
|
/* Must have at least 1 element */
|
|
datalist1:
|
|
dataitem
|
|
| datalist ',' dataitem
|
|
;
|
|
|
|
dataitem:
|
|
constdata
|
|
| '{' datalist '}'
|
|
;
|
|
|
|
constdata:
|
|
simpleconstant
|
|
| OPAQUESTRING
|
|
| FILLMARKER
|
|
| NIL
|
|
| econstref
|
|
| function
|
|
;
|
|
|
|
econstref: path ;
|
|
|
|
function: ident '(' arglist ')' ;
|
|
|
|
arglist:
|
|
simpleconstant
|
|
| arglist ',' simpleconstant
|
|
;
|
|
|
|
simpleconstant:
|
|
CHAR_CONST /* never used apparently*/
|
|
| BYTE_CONST
|
|
| SHORT_CONST
|
|
| INT_CONST
|
|
| INT64_CONST
|
|
| UBYTE_CONST
|
|
| USHORT_CONST
|
|
| UINT_CONST
|
|
| UINT64_CONST
|
|
| FLOAT_CONST
|
|
| DOUBLE_CONST
|
|
| TERMSTRING
|
|
;
|
|
|
|
intlist:
|
|
constint
|
|
| intlist ',' constint
|
|
;
|
|
|
|
constint:
|
|
INT_CONST
|
|
| UINT_CONST
|
|
| INT64_CONST
|
|
| UINT64_CONST
|
|
;
|
|
|
|
conststring: TERMSTRING ;
|
|
|
|
constbool:
|
|
conststring
|
|
| constint
|
|
;
|
|
|
|
/* Push all idents thru here for tracking */
|
|
ident: IDENT ;
|
|
.fi
|
|
.RE
|