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731 lines
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731 lines
24 KiB
Plaintext
/*!
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\page dap2 DAP2 Support
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\tableofcontents
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\section dap_introduction DAP2 (OPeNDAP) Introduction
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Beginning with netCDF version 4.1, optional support is provided for
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accessing data through OPeNDAP servers using the DAP protocol.
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Currently, only DAP protocol version 2 is supported; DAP protocol
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version 4 support is under development.
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DAP support is automatically enabled if a usable curl library can be
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set using the LDFLAGS environment variable (similar to the way
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that the HDF5 libraries are referenced).
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DAP support can forcibly be enabled or disabled using the --enable-dap
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flag or the --disable-dap flag, respectively. If enabled,
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then DAP2 support requires access to the curl library.
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Refer to the installation manual for details
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DAP uses a data model that is different from that supported by netCDF,
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either classic or enhanced. Generically, the DAP data model is encoded
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textually in a DDS (Dataset Descriptor Structure). There is a second
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data model for DAP attributes, which is encoded textually in a DAS
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(Dataset Attribute Structure). For detailed information about the DAP
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DDS and DAS, refer to the OPeNDAP web site http://opendap.org.
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\subsection dap_dap_information OPeNDAP Documentation
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See the following pages for more information.
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- \subpage dap_accessing_data
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- <a href="auth.md">netCDF Authorization Support</a>
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- \subpage dap_to_netcdf
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- \subpage dap2_reserved_keywords
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- \subpage var_dim_trans
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- \subpage var_name_trans
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\section dap_accessing_data Accessing OPeNDAP Data
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In order to access an OPeNDAP data source through the netCDF API, the
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file name normally used is replaced with a URL with a specific
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format. The URL is composed of three parts.
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- URL - this is a standard form URL such as
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http://remotetest.unidata.ucar.edu/dts/test.01
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- Constraints - these are suffixed to the URL and take the form
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“?\<projections>&\<selections>”. The meaning of the terms projection
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and selection is somewhat complicated; and the OPeNDAP web site,
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http://www.opendap.org , should be consulted. The interaction of DAP
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constraints with netCDF is complex and at the moment requires an
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understanding of how DAP is translated to netCDF.
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- Client parameters - these may be specified in either of
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two ways. The older, deprecated form prefixes text to the
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front of the url and is of the the general form [\<name>]
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or [\<name>=value]. Examples include [show=fetch] and
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[noprefetch]. The newer, preferred form prefixes the
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parameters to the end of the url using the semi-standard '#'
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format: e.g. http://....#show=fetch&noprefetch.
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It is possible to see what the translation does to a particular DAP
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data source in either of two ways. First, one can examine the DDS
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source through a web browser and then examine the translation using
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the ncdump -h command to see the netCDF Classic translation. The
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ncdump output will actually be the union of the DDS with the DAS, so
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to see the complete translation, it is necessary to view both.
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For example, if a web browser is given the following, the first URL
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will return the DDS for the specified dataset, and the second URL will
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return the DAS for the specified dataset.
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\code
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http://remotetest.unidata.ucar.edu/dts/test.01.dds
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http://remotetest.unidata.ucar.edu/dts/test.01.das
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\endcode
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Then by using the following ncdump command, it is possible to see the
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equivalent netCDF Classic translation.
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\code
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ncdump -h http://remotetest.unidata.ucar.edu/dts/test.01
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\endcode
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The DDS output from the web server should look like this.
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\code
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Dataset {
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Byte b;
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Int32 i32;
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UInt32 ui32;
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Int16 i16;
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UInt16 ui16;
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Float32 f32;
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Float64 f64;
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String s;
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Url u;
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} SimpleTypes;
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\endcode
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The DAS output from the web server should look like this.
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\code
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Attributes {
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Facility {
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String PrincipleInvestigator ``Mark Abbott'', ``Ph.D'';
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String DataCenter ``COAS Environmental Computer Facility'';
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String DrifterType ``MetOcean WOCE/OCM'';
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}
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b {
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String Description ``A test byte'';
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String units ``unknown'';
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}
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i32 {
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String Description ``A 32 bit test server int'';
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String units ``unknown'';
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}
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}
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\endcode
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The output from ncdump should look like this.
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\code
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netcdf test {
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dimensions:
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stringdim64 = 64 ;
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variables:
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byte b ;
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b:Description = "A test byte" ;
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b:units = "unknown" ;
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int i32 ;
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i32:Description = "A 32 bit test server int" ;
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i32:units = "unknown" ;
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int ui32 ;
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short i16 ;
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short ui16 ;
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float f32 ;
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double f64 ;
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char s(stringdim64) ;
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char u(stringdim64) ;
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}
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\endcode
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Note that the fields of type String and type URL have suddenly
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acquired a dimension. This is because strings are translated to arrays
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of char, which requires adding an extra dimension. The size of the
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dimension is determined in a variety of ways and can be specified. It
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defaults to 64 and when read, the underlying string is either padded
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or truncated to that length.
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Also note that the Facility attributes do not appear in the
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translation because they are neither global nor associated with a
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variable in the DDS.
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Alternately, one can get the text of the DDS as a global attribute by
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using the client parameters mechanism . In this case, the parameter
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“show=dds” can be used, and the data retrieved using
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the following command
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\code
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ncdump -h http://remotetest.unidata.ucar.edu/dts/test.01.dds#show=dds
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\endcode
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The ncdump -h command will then show both the translation and the
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original DDS. In the above example, the DDS would appear as the global
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attribute “_DDS” as follows.
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\code
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netcdf test {
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...
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variables:
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:_DDS = "Dataset { Byte b; Int32 i32; UInt32 ui32; Int16 i16;
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UInt16 ui16; Float32 f32; Float64 f64;
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Strings; Url u; } SimpleTypes;"
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byte b ;
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...
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}
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\endcode
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\section dap_to_netcdf DAP to NetCDF Translation Rules
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Currently only one translation available: DAP 2 Protocol to netCDF-3.
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There used to be a DAP 2 Protocol to netCDF-4 translation
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but that has been removed until the DAP4 protocol is available.
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\subsection nc3_trans_rules netCDF-3 Translation Rules
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The current default translation code translates the OPeNDAP protocol
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to netCDF-3 (classic). This netCDF-3 translation converts an OPeNDAP
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DAP protocol version 2 DDS to netCDF-3 and is designed to mimic as
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closely as possible the translation provided by the libnc-dap
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system, except that some errors in that older translation have
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been fixed.
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For illustrative purposes, the following example will be used.
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\code
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Dataset {
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Int32 f1;
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Structure {
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Int32 f11;
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Structure {
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Int32 f1[3];
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Int32 f2;
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} FS2[2];
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} S1;
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Structure {
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Grid {
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Array:
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Float32 temp[lat=2][lon=2];
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Maps:
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Int32 lat[lat=2];
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Int32 lon[lon=2];
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} G1;
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} S2;
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Grid {
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Array:
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Float32 G2[lat=2][lon=2];
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Maps:
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Int32 lat[2];
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Int32 lon[2];
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} G2;
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Int32 lat[lat=2];
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Int32 lon[lon=2];
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} D1;
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\endcode
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\subsection var_def Variable Definition
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The set of netCDF variables is derived from the fields with primitive
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base types as they occur in Sequences, Grids, and Structures. The
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field names are modified to be fully qualified initially. For the
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above, the set of variables are as follows. The coordinate variables
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within grids are left out in order to mimic the behavior of libnc-dap.
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\code
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f1
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S1.f11
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S1.FS2.f1
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S1.FS2.f2
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S2.G1.temp
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S2.G2.G2
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lat
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lon
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\endcode
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\section dap2_reserved_keywords DAP2 Reserved Keywords
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In the OPeNDAP DAP2 protocol, there are a number of reserved keywords. These keywords are case insensitive and if you use one as a netCDF variable name, you may encounter odd behavior such as case changes (depending on the client DDS/DAS parser). The list of reserved keywords as used by the netCDF-C library parser are as follows:
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- alias
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- array
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- attributes
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- byte
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- dataset
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- error
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- float32
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- float64
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- grid
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- int16
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- int32
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- maps
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- sequence
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- string
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- structure
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- uint16
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- uint32
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- url
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- code
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- message
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- program_type
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- program
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\section var_dim_trans Variable Dimension Translation
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A variable's rank is determined from three sources.
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- The variable has the dimensions associated with the field it
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represents (e.g. S1.FS2.f1[3] in the above example).
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- The variable inherits the dimensions associated with any containing
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structure that has a rank greater than zero. These dimensions precede
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those of case 1. Thus, we have in our example, f1[2][3], where the
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first dimension comes from the containing Structure FS2[2].
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- The variable's set of dimensions are altered if any of its
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containers is a DAP DDS Sequence. This is discussed more fully below.
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If the type of the netCDF variable is char, then an extra string
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dimension is added as the last dimension.
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\subsection dim_trans Dimension translation
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For dimensions, the rules are as follows.
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Fields in dimensioned structures inherit the dimension of the
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structure; thus the above list would have the following dimensioned
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variables.
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\code
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S1.FS2.f1 -> S1.FS2.f1[2][3]
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S1.FS2.f2 -> S1.FS2.f2[2]
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S2.G1.temp -> S2.G1.temp[lat=2][lon=2]
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S2.G1.lat -> S2.G1.lat[lat=2]
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S2.G1.lon -> S2.G1.lon[lon=2]
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S2.G2.G2 -> S2.G2.lon[lat=2][lon=2]
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S2.G2.lat -> S2.G2.lat[lat=2]
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S2.G2.lon -> S2.G2.lon[lon=2]
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lat -> lat[lat=2]
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lon -> lon[lon=2]
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\endcode
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Collect all of the dimension specifications from the DDS, both named
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and anonymous (unnamed) For each unique anonymous dimension with value
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NN create a netCDF dimension of the form "XX_<i>=NN", where XX is the
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fully qualified name of the variable and i is the i'th (inherited)
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dimension of the array where the anonymous dimension occurs. For our
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example, this would create the following dimensions.
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\code
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S1.FS2.f1_0 = 2 ;
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S1.FS2.f1_1 = 3 ;
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S1.FS2.f2_0 = 2 ;
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S2.G2.lat_0 = 2 ;
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S2.G2.lon_0 = 2 ;
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\endcode
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If however, the anonymous dimension is the single dimension of a MAP
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vector in a Grid then the dimension is given the same name as the map
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vector This leads to the following.
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\code
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S2.G2.lat_0 -> S2.G2.lat
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S2.G2.lon_0 -> S2.G2.lon
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\endcode
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For each unique named dimension "<name>=NN", create a netCDF dimension
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of the form "<name>=NN", where name has the qualifications removed. If
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this leads to duplicates (i.e. same name and same value), then the
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duplicates are ignored. This produces the following.
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\code
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S2.G2.lat -> lat
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S2.G2.lon -> lon
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\endcode
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Note that this produces duplicates that will be ignored later.
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At this point the only dimensions left to process should be named
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dimensions with the same name as some dimension from step number 3,
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but with a different value. For those dimensions create a dimension of
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the form "<name>M=NN" where M is a counter starting at 1. The example
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has no instances of this.
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Finally and if needed, define a single UNLIMITED dimension named
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"unlimited" with value zero. Unlimited will be used to handle certain
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kinds of DAP sequences (see below).
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This leads to the following set of dimensions.
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\code
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dimensions:
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unlimited = UNLIMITED;
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lat = 2 ;
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lon = 2 ;
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S1.FS2.f1_0 = 2 ;
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S1.FS2.f1_1 = 3 ;
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S1.FS2.f2_0 = 2 ;
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\endcode
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\section var_name_trans Variable Name Translation
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The steps for variable name translation are as follows.
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Take the set of variables captured above. Thus for the above DDS, the
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following fields would be collected.
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\code
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f1
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S1.f11
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S1.FS2.f1
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S1.FS2.f2
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S2.G1.temp
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S2.G2.G2
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lat
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lon
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\endcode
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All grid array variables are renamed to be the same as the containing
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grid and the grid prefix is removed. In the above DDS, this results in
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the following changes.
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\code
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G1.temp -> G1
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G2.G2 -> G2
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\endcode
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It is important to note that this process could produce duplicate
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variables (i.e. with the same name); in that case they are all assumed
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to have the same content and the duplicates are ignored. If it turns
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out that the duplicates have different content, then the translation
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will not detect this. YOU HAVE BEEN WARNED.
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The final netCDF-3 schema (minus attributes) is then as follows.
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\code
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netcdf t {
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dimensions:
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unlimited = UNLIMITED ;
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lat = 2 ;
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lon = 2 ;
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S1.FS2.f1_0 = 2 ;
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S1.FS2.f1_1 = 3 ;
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S1.FS2.f2_0 = 2 ;
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variables:
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int f1 ;
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int lat(lat) ;
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int lon(lon) ;
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int S1.f11 ;
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int S1.FS2.f1(S1.FS2.f1_0, S1.FS2.f1_1) ;
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int S1.FS2.f2(S1_FS2_f2_0) ;
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float S2.G1(lat, lon) ;
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float G2(lat, lon) ;
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}
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\endcode
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In actuality, the unlimited dimension is dropped because it is unused.
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There are differences with the original libnc-dap here because
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libnc-dap technically was incorrect. The original would have said
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this, for example.
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\code
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int S1.FS2.f1(lat, lat) ;
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\endcode
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Note that this is incorrect because it dimensions S1.FS2.f1(2,2)
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rather than S1.FS2.f1(2,3).
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\subsection dap_translation Translating DAP DDS Sequences
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Any variable (as determined above) that is contained directly or
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indirectly by a Sequence is subject to revision of its rank using the
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following rules.
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Let the variable be contained in Sequence Q1, where Q1 is the
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innermost containing sequence. If Q1 is itself contained (directly or
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indirectly) in a sequence, or Q1 is contained (again directly or
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indirectly) in a structure that has rank greater than 0, then the
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variable will have an initial UNLIMITED dimension. Further, all
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dimensions coming from "above" and including (in the containment
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sense) the innermost Sequence, Q1, will be removed and replaced by
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that single UNLIMITED dimension. The size associated with that
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UNLIMITED is zero, which means that its contents are inaccessible
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through the netCDF-3 API. Again, this differs from libnc-dap, which
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leaves out such variables. Again, however, this difference is backward
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compatible.
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If the variable is contained in a single Sequence (i.e. not nested)
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and all containing structures have rank 0, then the variable will have
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an initial dimension whose size is the record count for that
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Sequence. The name of the new dimension will be the name of the
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Sequence.
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Consider this example.
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\code
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Dataset {
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Structure {
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Sequence {
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Int32 f1[3];
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Int32 f2;
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} SQ1;
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} S1[2];
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Sequence {
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Structure {
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Int32 x1[7];
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} S2[5];
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} Q2;
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} D;
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\endcode
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The corresponding netCDF-3 translation is pretty much as follows (the
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value for dimension Q2 may differ).
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\code
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dimensions:
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unlimited = UNLIMITED ; // (0 currently)
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S1.SQ1.f1_0 = 2 ;
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S1.SQ1.f1_1 = 3 ;
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S1.SQ1.f2_0 = 2 ;
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Q2.S2.x1_0 = 5 ;
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Q2.S2.x1_1 = 7 ;
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Q2 = 5 ;
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variables:
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int S1.SQ1.f1(unlimited, S1.SQ1.f1_1) ;
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int S1.SQ1.f2(unlimited) ;
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int Q2.S2.x1(Q2, Q2.S2.x1_0, Q2.S2.x1_1) ;
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\endcode
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Note that for example S1.SQ1.f1_0 is not actually used because it has
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been folded into the unlimited dimension.
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Note that for sequences without a leading unlimited dimension, there
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is a performance cost because the translation code has to walk the
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data to determine how many records are associated with the
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sequence. Since libnc-dap did essentially the same thing, it can be
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assumed that the cost is not prohibitive.
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\section dap_caching Caching
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In an effort to provide better performance for some access patterns,
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client-side caching of data is available. The default is no caching,
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but it may be enabled by prefixing the URL with the parameter "cache".
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Caching operates basically as follows.
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When a URL is first accessed using nc_open(), netCDF automatically
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does a pre-fetch of selected variables. These include all variables
|
|
smaller than a specified (and user definable) size. This allows, for
|
|
example, quick access to coordinate variables. This can be suppressed
|
|
with the parameter "noprefetch".
|
|
|
|
Whenever a request is made using some variant of the nc_get_var() API
|
|
procedures, the complete variable is fetched and stored in the cache
|
|
as a new cache entry. Subsequence requests for any part of that
|
|
variable will access the cache entry to obtain the data.
|
|
|
|
The cache may become too full, either because there are too many
|
|
entries or because it is taking up too much disk space. In this case
|
|
cache entries are purged until the cache size limits are reached. The
|
|
cache purge algorithm is LRU (least recently used) so that variables
|
|
that are repeatedly referenced will tend to stay in the cache.
|
|
|
|
The cache is completely purged when nc_close() is invoked.
|
|
|
|
In order to decide if you should enable caching, you will need to have
|
|
some understanding of the access patterns of your program.
|
|
|
|
The ncdump program always dumps one or more whole variables so it
|
|
turns on caching.
|
|
|
|
If your program accesses only parts of a number of variables, then
|
|
caching should probably not be used since fetching whole variables
|
|
will probably slow down your program for no purpose.
|
|
|
|
Unfortunately, caching is currently an all or nothing proposition, so
|
|
for more complex access patterns, the decision to cache or not may not
|
|
have an obvious answer. Probably a good rule of thumb is to avoid
|
|
caching initially and later turn it on to see its effect on
|
|
performance.
|
|
|
|
\section dap_defined_params Defined Client Parameters
|
|
|
|
Currently, a limited set of client parameters is
|
|
recognized. Parameters not listed here are ignored, but no error is
|
|
signalled. All names are case insensitive.
|
|
|
|
Parameter Name Legal Values Semantics
|
|
- "log" | "log=<file>" - Turn on logging and send the log output to
|
|
the specified file. If no file is specified, then output is sent to standard
|
|
error.
|
|
- "show=... das|dds|url" - This causes information to appear as
|
|
specific global attributes. The currently recognized tags are "dds"
|
|
to display the underlying DDS, "das" similarly, and "url" to display
|
|
the url used to retrieve the data. This parameter may be specified
|
|
multiple times (e.g. “show=dds&show=url”).
|
|
- "show=fetch" - This parameter causes the netCDF code to log a copy
|
|
of the complete url for every HTTP get request. If logging is
|
|
enabled, then this can be helpful in checking to see the access
|
|
behavior of the netCDF code.
|
|
- "stringlength=NN" - Specify the default string length to use for
|
|
string dimensions. The default is 64. The name "maxstrlen" is an
|
|
alias for "stringlength".
|
|
- "stringlength_<var>=NN" - Specify the default string length to use
|
|
for a string dimension for the specified variable. The default is
|
|
64. The name "maxstrlen_<var>" is an alias for "stringlength_<var>".
|
|
- "cache" - This enables caching.
|
|
- "nocache" - This disbles caching.
|
|
- "cachelimit=NN" - Specify the maximum amount of space allowed for
|
|
the cache.
|
|
- "cachecount=NN" - Specify the maximum number of entries in the
|
|
cache.
|
|
- "prefetch" - This enables prefetch of small variables (default).
|
|
- "noprefetch" - This disables prefetch of small variables.
|
|
- "fillmismatch" - This enables _FillValue/Variable type mismatch.
|
|
- "nofillmismatch" - This disables _FillValue/Variable type mismatch (default).
|
|
|
|
\section dap_debug Notes on Debugging OPeNDAP Access
|
|
|
|
The OPeNDAP support makes use of the logging facility of the
|
|
underlying oc system (see http://www.opendap.org/oc).
|
|
Note that this is currently separate from the
|
|
existing netCDF logging facility. Turning on this logging can
|
|
sometimes give important information. Logging can be enabled by
|
|
using the client parameter "log" or "log=filename",
|
|
where the first case will send log output to standard error and the
|
|
second will send log output to the specified file.
|
|
|
|
Users should also be aware that if one is
|
|
accessing data over an NFS mount, one may see some .nfsxxxxx files;
|
|
those can be ignored.
|
|
|
|
\subsection http_config HTTP Configuration.
|
|
|
|
Limited support for configuring the http connection is provided via
|
|
parameters in the “.dodsrc” configuration file. The relevant .dodsrc file is
|
|
located by first looking in the current working directory, and if not
|
|
found, then looking in the directory specified by the “$HOME”
|
|
environment variable.
|
|
|
|
Entries in the .dodsrc file are of the form:
|
|
|
|
\code
|
|
['['<url>']']<key>=<value>
|
|
\endcode
|
|
|
|
That is, it consists of a key name and value pair and optionally
|
|
preceded by a url enclosed in square brackets.
|
|
|
|
For given KEY and URL strings, the value chosen is as follows:
|
|
|
|
If URL is null, then look for the .dodsrc entry that has no url prefix
|
|
and whose key is same as the KEY for which we are looking.
|
|
|
|
If the URL is not null, then look for all the .dodsrc entries that
|
|
have a url, URL1, say, and for which URL1 is a prefix (in the string
|
|
sense) of URL. For example, if URL = http//x.y/a, then it will match
|
|
entries of the form
|
|
|
|
\code
|
|
1. [http//x.y/a]KEY=VALUE
|
|
2. [http//x.y/a/b]KEY=VALUE
|
|
\endcode
|
|
|
|
It will not match an entry of the form
|
|
|
|
\code
|
|
[http//x.y/b]KEY=VALUE
|
|
\endcode
|
|
|
|
because “http://x.y/b” is not a string prefix of
|
|
“http://x.y/a”. Finally from the set so constructed, choose the entry
|
|
with the longest url prefix: “http//x.y/a/b]KEY=VALUE” in this case.
|
|
|
|
Currently, the supported set of keys (with descriptions) are as
|
|
follows.
|
|
|
|
<pre>
|
|
HTTP.VERBOSE
|
|
Type: boolean ("1"/"0")
|
|
Description: Produce verbose output, especially using SSL.
|
|
Related CURL Flags: CURLOPT_VERBOSE
|
|
HTTP.DEFLATE
|
|
Type: boolean ("1"/"0")
|
|
Description: Allow use of compression by the server.
|
|
Related CURL Flags: CURLOPT_ENCODING
|
|
HTTP.COOKIEJAR
|
|
Type: String representing file path
|
|
Description: Specify the name of file into which to store cookies. Defaults to in-memory storage.
|
|
Related CURL Flags:CURLOPT_COOKIEJAR
|
|
HTTP.CREDENTIALS.USER
|
|
Type: String representing user name
|
|
Description: Specify the user name for Digest and Basic authentication.
|
|
Related CURL Flags:
|
|
HTTP.CREDENTIALS.PASSWORD
|
|
Type: String representing password
|
|
Type: boolean ("1"/"0")
|
|
Description: Specify the password for Digest and Basic authentication.
|
|
Related CURL Flags:
|
|
HTTP.SSL.CERTIFICATE
|
|
Type: String representing file path
|
|
Description: Path to a file containing a PEM cerficate.
|
|
Related CURL Flags: CURLOPT_CERT
|
|
HTTP.SSL.KEY
|
|
Type: String representing file path
|
|
Description: Same as HTTP.SSL.CERTIFICATE, and should usually have the same value.
|
|
Related CURL Flags: CURLOPT_SSLKEY
|
|
HTTP.SSL.KEYPASSWORD
|
|
Type: String representing password
|
|
Description: Password for accessing the HTTP.SSL.KEY/HTTP.SSL.CERTIFICATE
|
|
Related CURL Flags: CURLOPT_KEYPASSWORD
|
|
HTTP.SSL.CAPATH
|
|
Type: String representing directory
|
|
Description: Path to a directory containing trusted certificates for validating server certificates.
|
|
Related CURL Flags: CURLOPT_CAPATH
|
|
HTTP.SSL.VALIDATE
|
|
Type: boolean ("1"/"0")
|
|
Description: Cause the client to verify the server's presented certificate.
|
|
Related CURL Flags: CURLOPT_SSL_VERIFYPEER, CURLOPT_SSL_VERIFYHOST
|
|
HTTP.TIMEOUT
|
|
Type: String ("dddddd")
|
|
Description: Specify the maximum time in seconds that you allow the http transfer operation to take.
|
|
Related CURL Flags: CURLOPT_TIMEOUT, CURLOPT_NOSIGNAL
|
|
HTTP.PROXY_SERVER
|
|
Type: String representing url to access the proxy: (e.g.http://[username:password@]host[:port])
|
|
Description: Specify the needed information for accessing a proxy.
|
|
Related CURL Flags: CURLOPT_PROXY, CURLOPT_PROXYHOST, CURLOPT_PROXYUSERPWD
|
|
HTTP.READ.BUFFERSIZE
|
|
Type: String ("dddddd")
|
|
Description: Specify the the internal buffer size for curl reads.
|
|
Related CURL Flags: CURLOPT_BUFFERSIZE, CURL_MAX_WRITE_SIZE (16kB),
|
|
CURL_MAX_READ_SIZE (512kB).
|
|
|
|
HTTP.KEEPALIVE
|
|
Type: String ("on|n/m")
|
|
Description: Specify that TCP KEEPALIVE should be enabled and that the associated idle wait time is n and that the associated repeat interval is m. If the value is of the form is the string "on", then turn on keepalive, but do not set idle or interval.
|
|
Related CURL Flags: CURLOPT_TCP_KEEPALIVE, CURLOPT_TCP_KEEPIDLE,
|
|
CURLOPT_TCP_KEEPINTVL.
|
|
</pre>
|
|
|
|
The related curl flags line indicates the curl flags modified by this
|
|
key. See the libcurl documentation of the curl_easy_setopt() function
|
|
for more detail (http://curl.haxx.se/libcurl/c/curl_easy_setopt.html).
|
|
|
|
For ESG client side key support, the following entries must be specified:
|
|
|
|
\code
|
|
HTTP.SSL.VALIDATE
|
|
HTTP.COOKIEJAR
|
|
HTTP.SSL.CERTIFICATE
|
|
HTTP.SSL.KEY
|
|
HTTP.SSL.CAPATH
|
|
\endcode
|
|
|
|
Additionally, for ESG, the HTTP.SSL.CERTIFICATE and HTTP.SSL.KEY
|
|
entries should have same value, which is the file path for the
|
|
certificate produced by MyProxyLogon. The HTTP.SSL.CAPATH entry should
|
|
be the path to the "certificates" directory produced by MyProxyLogon.
|
|
|
|
*/
|