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Inheritance Hierarchy for Exceptions in Ruby
The mapping for exceptions is based on the inheritance hierarchy shown below:
Inheritance structure for Ice exceptions.
The ancestor of all exceptions is StandardError
, from which Ice::Exception
is derived. Ice::LocalException
and Ice::UserException
are derived from Ice::Exception
and form the base for all run-time and user exceptions.
Ruby Mapping for User Exceptions
Here is a fragment of the Slice definition for our world time server once more:
exception GenericError { string reason; } exception BadTimeVal extends GenericError {} exception BadZoneName extends GenericError {}
These exception definitions map to the abbreviated Ruby class definitions shown below:
class GenericError < Ice::UserException def initialize(reason='') def to_s def inspect attr_accessor :reason end class BadTimeVal < GenericError def initialize(reason='') def to_s def inspect end class BadZoneName < GenericError def initialize(reason='') def to_s def inspect end
Each Slice exception is mapped to a Ruby class with the same name. The inheritance structure of the Slice exceptions is preserved for the generated classes, so BadTimeVal
and BadZoneName
inherit from GenericError
.
Each exception member corresponds to an instance variable of the instance, which the constructor initializes to a default value appropriate for its type:
Data Member Type | Default Value |
---|---|
string | Empty string |
enum | First enumerator in enumeration |
struct | Default-constructed value |
Numeric | Zero |
bool | False |
sequence | Null |
dictionary | Null |
class /interface | Null |
You can also declare different default values for members of primitive and enumerated types. For derived exceptions, the constructor has one parameter for each of the base exception's data members, plus one parameter for each of the derived exception's data members, in base-to-derived order. As an example, although BadTimeVal
and BadZoneName
do not declare data members, their constructors still accept a value for the inherited data member reason
in order to pass it to the constructor of the base exception GenericError
. The generated class defines an accessor for each data member to read and write its value.
Each exception also defines the standard methods to_s
and inspect
that return the Slice type ID of the exception and a stringified representation of the exception and its members, respectively. The method ice_id
returns the same as to_s
.
All user exceptions are derived from the base class Ice::UserException
. This allows you to catch all user exceptions generically by installing a handler for Ice::UserException
. Similarly, you can catch all Ice run-time exceptions with a handler for Ice::LocalException
, and you can catch all Ice exceptions with a handler for Ice::Exception
.
Optional Data Members
Optional data members use the same mapping as required data members, but an optional data member can also be set to the marker value Ice::Unset
to indicate that the member is unset. A well-behaved program must compare an optional data member to Ice::Unset
before using the member's value:
begin ... rescue => ex if ex.optionalMember == Ice::Unset puts "optionalMember is unset" else puts "optionalMember = " + ex.optionalMember end end
The Ice::Unset
marker value has different semantics than nil
. Since nil
is a legal value for certain Slice types, the Ice run time requires a separate marker value so that it can determine whether an optional value is set. An optional value set to nil
is considered to be set. If you need to distinguish between an unset value and a value set to nil
, you can do so as follows:
begin ... rescue => ex if ex.optionalMember == Ice::Unset puts "optionalMember is unset" elsif ex.optionalMember == nil puts "optionalMember is nil" else puts "optionalMember = " + ex.optionalMember end end
Ruby Mapping for Run-Time Exceptions
The Ice run time throws run-time exceptions for a number of pre-defined error conditions. All run-time exceptions directly or indirectly derive from Ice::LocalException
(which, in turn, derives from Ice::Exception
).
By catching exceptions at the appropriate point in the inheritance hierarchy, you can handle exceptions according to the category of error they indicate:
Ice::LocalException
This is the root of the inheritance tree for run-time exceptions.
Ice::UserException
This is the root of the inheritance tree for user exceptions.
Ice::TimeoutException
This is the base exception for both operation-invocation and connection-establishment timeouts.
Ice::ConnectTimeoutException
This exception is raised when the initial attempt to establish a connection to a server times out.
For example, a ConnectTimeoutException
can be handled as ConnectTimeoutException
, TimeoutException
, LocalException
, or Exception
.
You will probably have little need to catch run-time exceptions as their most-derived type and instead catch them as LocalException
; the fine-grained error handling offered by the remainder of the hierarchy is of interest mainly in the implementation of the Ice run time. Exceptions to this rule are the exceptions related to facet and object life cycles, which you may want to catch explicitly. These exceptions are FacetNotExistException
and ObjectNotExistException
, respectively.
See Also
- User Exceptions
- Run-Time Exceptions
- Ruby Mapping for Identifiers
- Ruby Mapping for Modules
- Ruby Mapping for Built-In Types
- Ruby Mapping for Enumerations
- Ruby Mapping for Structures
- Ruby Mapping for Sequences
- Ruby Mapping for Dictionaries
- Ruby Mapping for Constants
- Optional Data Members
- Versioning
- Object Life Cycle