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305 lines
14 KiB
Plaintext
/** \file types.dox Documentation related to NetCDF Types
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Documentation of types.
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\page data_type Data Types
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\tableofcontents
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Data in a netCDF file may be one of the \ref external_types, or may be
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a user-defined data type (see \ref user_defined_types).
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\section external_types External Data Types
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The atomic external types supported by the netCDF interface are:
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- ::NC_BYTE 8-bit signed integer
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- ::NC_UBYTE 8-bit unsigned integer *
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- ::NC_CHAR 8-bit character
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- ::NC_SHORT 16-bit signed integer
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- ::NC_USHORT 16-bit unsigned integer *
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- ::NC_INT (or ::NC_LONG) 32-bit signed integer
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- ::NC_UINT 32-bit unsigned integer *
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- ::NC_INT64 64-bit signed integer *
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- ::NC_UINT64 64-bit unsigned integer *
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- ::NC_FLOAT 32-bit floating point
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- ::NC_DOUBLE 64-bit floating point
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- ::NC_STRING variable length character string +
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\remark * These types are available only for CDF5 (NC_CDF5) and netCDF-4 format (NC_NETCDF4) files. All the unsigned ints and the 64-bit ints are for CDF5 or netCDF-4 files only.
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\remark + These types are available only for netCDF-4 (NC_NETCDF4) files.
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These types were chosen to provide a reasonably wide range of
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trade-offs between data precision and number of bits required for each
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value. These external data types are independent from whatever
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internal data types are supported by a particular machine and language
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combination.
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These types are called "external", because they correspond to the
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portable external representation for netCDF data. When a program reads
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external netCDF data into an internal variable, the data is converted,
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if necessary, into the specified internal type. Similarly, if you
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write internal data into a netCDF variable, this may cause it to be
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converted to a different external type, if the external type for the
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netCDF variable differs from the internal type.
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The separation of external and internal types and automatic type
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conversion have several advantages. You need not be aware of the
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external type of numeric variables, since automatic conversion to or
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from any desired numeric type is available. You can use this feature
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to simplify code, by making it independent of external types, using a
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sufficiently wide internal type, e.g., double precision, for numeric
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netCDF data of several different external types. Programs need not be
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changed to accommodate a change to the external type of a variable.
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If conversion to or from an external numeric type is necessary, it is
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handled by the library.
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Converting from one numeric type to another may result in an error if
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the target type is not capable of representing the converted
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value. For example, an internal short integer type may not be able to
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hold data stored externally as an integer. When accessing an array of
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values, a range error is returned if one or more values are out of the
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range of representable values, but other values are converted
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properly.
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Note that mere loss of precision in type conversion does not return an
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error. Thus, if you read double precision values into a
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single-precision floating-point variable, for example, no error
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results unless the magnitude of the double precision value exceeds the
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representable range of single-precision floating point numbers on your
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platform. Similarly, if you read a large integer into a float
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incapable of representing all the bits of the integer in its mantissa,
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this loss of precision will not result in an error. If you want to
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avoid such precision loss, check the external types of the variables
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you access to make sure you use an internal type that has adequate
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precision.
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The names for the primitive external data types (char, byte, ubyte, short,
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ushort, int, uint, int64, uint64, float or real, double, string) are
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reserved words in CDL, so the names of variables, dimensions, and
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attributes must not be type names.
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It is possible to interpret byte data as either signed (-128 to 127)
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or unsigned (0 to 255). However, when reading byte data to be
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converted into other numeric types, it is interpreted as signed.
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For the correspondence between netCDF external data types and the data
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types of a language see \ref variables.
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\section classic_structures Data Structures in Classic Files
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The only kind of data structure directly supported by the netCDF
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classic abstraction, i.e. CDF-1, 2, and 5 formats, is a collection of named
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arrays with attached vector attributes. NetCDF is not particularly
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well-suited for storing linked lists, trees, sparse matrices, ragged
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arrays or other kinds of data structures requiring pointers.
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It is possible to build other kinds of data structures in netCDF
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classic formats, from sets of arrays by adopting
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various conventions regarding the use of data in one array as pointers
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into another array. The netCDF library won't provide much help or
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hindrance with constructing such data structures, but netCDF provides
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the mechanisms with which such conventions can be designed.
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The following netCDF classic example stores a ragged array ragged_mat
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using an attribute row_index to name an associated index variable
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giving the index of the start of each row. In this example, the first
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row contains 12 elements, the second row contains 7 elements (19 -
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12), and so on. (NetCDF-4 includes native support for variable length
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arrays. See below.)
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\code
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float ragged_mat(max_elements);
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ragged_mat:row_index = "row_start";
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int row_start(max_rows);
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data:
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row_start = 0, 12, 19, ...
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\endcode
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As another example, netCDF variables may be grouped within a netCDF
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classic dataset by defining attributes that list the
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names of the variables in each group, separated by a conventional
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delimiter such as a space or comma. Using a naming convention for
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attribute names for such groupings permits any number of named groups
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of variables. A particular conventional attribute for each variable
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might list the names of the groups of which it is a member. Use of
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attributes, or variables that refer to other attributes or variables,
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provides a flexible mechanism for representing some kinds of complex
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structures in netCDF datasets.
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\section nc4_user_defined_types NetCDF-4 User Defined Data Types
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NetCDF supported six data types through version 3.6.0 (char, byte,
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short, int, float, and double). Starting with version 4.0, many new
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data types are supported (unsigned int types, strings, compound types,
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variable length arrays, enums, opaque).
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In addition to the new atomic types the user may define types.
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Types are defined in define mode, and must be fully defined before
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they are used. New types may be added to a file by re-entering define
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mode.
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Once defined the type may be used to create a variable or attribute.
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Types may be nested in complex ways. For example, a compound type
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containing an array of VLEN types, each containing variable length
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arrays of some other compound type, etc. Users are cautioned to keep
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types simple. Reading data of complex types can be challenging for
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Fortran users.
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Types may be defined in any group in the data file, but they are
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always available globally in the file.
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Types cannot have attributes (but variables of the type may have
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attributes).
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Only files created with the netCDF-4/HDF5 mode flag (::NC_NETCDF4) but
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without the classic model flag (::NC_CLASSIC_MODEL) may use
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user-defined types or the new atomic data types.
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Once types are defined, use their ID like any other type ID when
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defining variables or attributes. Use functions
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- nc_put_att() / nc_get_att()
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- nc_put_var() / nc_get_var()
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- nc_put_var1() / nc_get_var1()
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- nc_put_vara() / nc_get_vara()
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- nc_put_vars() / nc_get_vars()
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functions to access attribute and variable data of user defined type.
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\subsection types_compound_types Compound Types
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Compound types allow the user to combine atomic and user-defined types
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into C-like structs. Since users defined types may be used within a
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compound type, they can contain nested compound types.
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Users define a compound type, and (in their C code) a corresponding C
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struct. They can then use nc_put_vara() and related functions to write
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multi-dimensional arrays of these structs, and nc_get_vara() calls
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to read them.
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While structs, in general, are not portable from platform to platform,
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the HDF5 layer (when installed) performs the magic required to figure
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out your platform's idiosyncrasies, and adjust to them. The end result
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is that HDF5 compound types (and therefore, netCDF-4 compound types),
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are portable.
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For more information on creating and using compound types, see
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Compound Types in The NetCDF C Interface Guide.
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\subsection vlen_types VLEN Types
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Variable length arrays can be used to create a ragged array of data,
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in which one of the dimensions varies in size from point to point.
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An example of VLEN use would the to store a 1-D array of dropsonde
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data, in which the data at each drop point is of variable length.
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There is no special restriction on the dimensionality of VLEN
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variables. It's possible to have 2D, 3D, 4D, etc. data, in which each
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point contains a VLEN.
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A VLEN has a base type (that is, the type that it is a VLEN of). This
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may be one of the atomic types (forming, for example, a variable
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length array of ::NC_INT), or it can be another user defined type,
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like a compound type.
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With VLEN data, special memory allocation and deallocation procedures
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must be followed, or memory leaks may occur.
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Compression is permitted but may not be effective for VLEN data,
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because the compression is applied to structures containing lengths
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and pointers to the data, rather than the actual data.
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For more information on creating and using variable length arrays, see
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Variable Length Arrays in The NetCDF C Interface Guide.
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\subsection types_opaque_types Opaque Types
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Opaque types allow the user to store arrays of data blobs of a fixed size.
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For more information on creating and using opaque types, see Opaque
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Type in The NetCDF C Interface Guide.
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\subsection enum_types Enum Types
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Enum types allow the user to specify an enumeration.
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For more information on creating and using enum types, see Enum Type
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in The NetCDF C Interface Guide.
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\section type_conversion Type Conversion
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Each netCDF variable has an external type, specified when the variable
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is first defined. This external type determines whether the data is
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intended for text or numeric values, and if numeric, the range and
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precision of numeric values.
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If the netCDF external type for a variable is char, only character
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data representing text strings can be written to or read from the
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variable. No automatic conversion of text data to a different
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representation is supported.
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If the type is numeric, however, the netCDF library allows you to
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access the variable data as a different type and provides automatic
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conversion between the numeric data in memory and the data in the
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netCDF variable. For example, if you write a program that deals with
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all numeric data as double-precision floating point values, you can
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read netCDF data into double-precision arrays without knowing or
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caring what the external type of the netCDF variables are. On reading
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netCDF data, integers of various sizes and single-precision
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floating-point values will all be converted to double-precision, if
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you use the data access interface for double-precision values. Of
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course, you can avoid automatic numeric conversion by using the netCDF
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interface for a value type that corresponds to the external data type
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of each netCDF variable, where such value types exist.
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The automatic numeric conversions performed by netCDF are easy to
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understand, because they behave just like assignment of data of one
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type to a variable of a different type. For example, if you read
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floating-point netCDF data as integers, the result is truncated
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towards zero, just as it would be if you assigned a floating-point
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value to an integer variable. Such truncation is an example of the
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loss of precision that can occur in numeric conversions.
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Converting from one numeric type to another may result in an error if
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the target type is not capable of representing the converted
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value. For example, an integer may not be able to hold data stored
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externally as an IEEE floating-point number. When accessing an array
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of values, a range error is returned if one or more values are out of
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the range of representable values, but other values are converted
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properly.
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Note that mere loss of precision in type conversion does not result in
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an error. For example, if you read double precision values into an
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integer, no error results unless the magnitude of the double precision
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value exceeds the representable range of integers on your
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platform. Similarly, if you read a large integer into a float
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incapable of representing all the bits of the integer in its mantissa,
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this loss of precision will not result in an error. If you want to
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avoid such precision loss, check the external types of the variables
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you access to make sure you use an internal type that has a compatible
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precision.
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Whether a range error occurs in writing a large floating-point value
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near the boundary of representable values may be depend on the
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platform. The largest floating-point value you can write to a netCDF
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float variable is the largest floating-point number representable on
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your system that is less than 2 to the 128th power. The largest double
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precision value you can write to a double variable is the largest
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double-precision number representable on your system that is less than
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2 to the 1024th power.
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The _uchar and _schar functions were introduced in netCDF-3 to
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eliminate an ambiguity, and support both signed and unsigned byte data.
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In netCDF-2, whether the external NC_BYTE type represented signed or
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unsigned values was left up to the user. In netcdf-3, we treat NC_BYTE
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as signed for the purposes of conversion to short, int, long, float, or
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double. (Of course, no conversion takes place when the internal type is
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signed char.) In the _uchar functions, we treat NC_BYTE as if it were
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unsigned. Thus, no NC_ERANGE error can occur converting between NC_BYTE
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and unsigned char.
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*/
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