ic
The Erlang IDL Compiler
The ic module is an Erlang implementation of an OMG IDL compiler. Depending on the choice of back-end the code will map to Erlang, C, or Java. The compiler generates client stubs and server skeletons.
Two kinds of files are generated for each scope: Ordinary code files and header files. The latter are used for defining record definitions, while the ordinary files contain the object interface functions.
Functions
ic:gen(FileName) -> Result
ic:gen(FileName, [Option]) -> Result
Result = ok | error | {ok, [Warning]} | {error, [Warning], [Error]}
Option = [ GeneralOption | CodeOption | WarningOption | BackendOption]
GeneralOption =
{outdir, String()} | {cfgfile, String()} | {use_preproc, bool()} |
{preproc_cmd, String()} | {preproc_flags, String()}
CodeOption =
{gen_hrl, bool()} | {serv_last_call, exception | exit} | {{impl, String()}, String()} | {light_ifr, bool()}
this | {this, String()} | {{this, String()}, bool()} |
from | {from, String()} | {{from, String()}, bool()} |
handle_info | {handle_info, String()} | {{handle_info, String()}, bool()} |
timeout | {timeout, String()} | {{timeout, String()}, bool()} |
{scoped_op_calls, bool()} | {scl, bool()} |
{user_protocol, Prefix} |
{c_timeout, {SendTimeout, RecvTimeout}} |
{c_report, bool()} |
{precond, {atom(), atom()}} | {{precond, String()} {atom(), atom()}} |
{postcond, {atom(), atom()}} | {{postcond, String()} {atom(), atom()}}
WarningOption =
{'Wall', bool()} | {maxerrs, int() | infinity} |
{maxwarns, int() | infinity} | {nowarn, bool()} |
{warn_name_shadow, bool()} | {pedantic, bool()} |
{silent, bool()}
BackendOption = {be, Backend}
Backend = erl_corba | erl_template | erl_plain | erl_genserv | c_client | c_server | java
DirNAme = string() | atom()
FileName = string() | atom()
The tuple {Option, true}
can be replaced by
Option
for boolean values.
The ic:gen/2
function can be called from the command
line as follows:
erlc "+Option" ... File.idl
Example:
erlc "+{be,c_client}" '+{outdir, "../out"}' File.idl
General options
Places all output files in the directory given by the option. The directory will be created if it does not already exist.
Example option: {outdir, "output/generated"}
.
Uses FileName as configuration file. Options will
override compiler defaults but can be overridden by command line
options. Default value is ".ic_config"
.
Example option: {cfgfile, "special.cfg"}
.
Uses a preprocessor. Default value is true.
Command string to invoke the preprocessor. The actual
command will be built as
preproc_cmd++preproc_flags++FileName
Example option: {preproc_cmd, "erl"})
.
Example option: {preproc_cmd, "gcc -x c++ -E"}
.
Flags given to the preprocessor.
Example option: {preproc_flags, "-I../include"}
.
Code options
Currently, the default setting is false
. To be able to
use this option Orber must be configured to use Light IFR (see
Orber's User's Guide). When this options is used, the size of the
generated files used to register the API in the IFR DB are minimized.
Example option: {light_ifr, true}
.
Generate header files. Default is true.
Makes the last gen_server handle_call
either raise a
CORBA exception or just exit plainly. Default is the exception.
Assumes that the interface with name IntfName is
implemented by the module with name ModName and
will generate calls to the ModName module in the
server behavior. Note that the IntfName must be a
fully scoped name as in "M1::I1"
.
Adds the object reference as the first parameter to the
object implementation functions. This makes the
implementation aware of its own object reference.
The option
comes in three varieties: this
which activates the
parameter for all interfaces in the source file, {this, IntfName}
which activates the parameter for a specified
interface and {{this, IntfName}, false}
which
deactivates the parameter for a specified
interface.
Example option: this)
activates the parameter for
all interfaces.
Example option: {this, "M1::I1"}
activates the
parameter for all functions of M1::I1
.
Example options: [this, {{this, "M1::I2"}, false}]
activates the parameter for all interfaces except
M1::I2
.
Adds the invokers reference as the first parameter to the
object implementation two-way functions. If both
from
and this
options are used the invokers
reference parameter will be passed as the second
parameter. This makes it possible for the implementation to
respond to a request and continue executing
afterwards. Consult the gen_server
and Orber
documentation how this option may be used.
The option
comes in three varieties: from
which activates the
parameter for all interfaces in the source file, {from, IntfName}
which activates the parameter for a specified
interface and {{from, IntfName}, false}
which
deactivates the parameter for a specified interface.
Example option: from)
activates the parameter for
all interfaces.
Example options: [{from, "M1::I1"}]
activates the
parameter for all functions of M1::I1
.
Example options: [from, {{from, "M1::I2"}, false}]
activates the parameter for all interfaces except
M1::I2
.
Makes the object server call a function handle_info
in the object implementation module on all unexpected
messages. Useful if the object implementation need to trap
exits.
Example option: handle_info
will activates module
implementation handle_info
for all interfaces in the
source file.
Example option: {{handle_info, "M1::I1"}, true}
will activates module implementation handle_info
for
the specified interface.
Example options: [handle_info, {{handle_info, "M1::I1"}, false}]
will generate the handle_info
call for all interfaces except M1::I1
.
Used to allow a server response time limit to be set by the user. This should be a string that represents the scope for the interface which should have an extra variable for wait time initialization.
Example option: {timeout,"M::I"})
produces server
stub which will has an extra timeout parameter in the initialization
function for that interface.
Example option: timeout
produces server
stub which will has an extra timeout parameter in the initialization
function for all interfaces in the source file.
Example options: [timeout, {{timeout,"M::I"}, false}]
produces server stub which will has an extra timeout
parameter in the initialization function for all interfaces
except M1::I1
.
Used to produce more refined request calls to server. When
this option is set to true, the operation name which was
mentioned in the call is scoped. This is essential to avoid
name clashes when communicating with c-servers. This option
is available for the c-client, c-server and the Erlang
gen_server back ends. All
of the parts generated by ic
have to agree in the use of this option. Default is
false
.
Example options:
[{be,c_genserv},{scoped_op_calls,true}])
produces
client stubs which sends "scoped" requests to a gen_server
or a c-server.
Used to define a own protocol different from the default Erlang distribution + gen_server protocol. Currently only valid for C back-ends. For further details see IC C protocol.
Example options:
[{be,c_client},{user_protocol, "my_special"}])
produces
client stubs which use C protocol functions with the prefix
"my_special".
Makes sends and receives to have timeouts (C back-ends only). These timeouts are specified in milliseconds.
Example options:
[{be,c_client},{c_timeout, {10000, 20000}}])
produces
client stubs which use a 10 seconds send timeout, and a
20 seconds receive timeout.
Generates code for writing encode/decode errors to stderr
(C back-ends only).
timeouts are specified in milliseconds.
Example options:
[{be,c_client}, c_report])
.
Used for compatibility with previous compiler versions up
to 3.3
. Due to better semantic checks on enumerants,
the compiler discovers name clashes between user defined
types and enumerant values in the same name space. By
enabling this option the compiler turns off the extended
semantic check on enumerant values. Default is
false
.
Example option: {scl,true}
Adds a precondition call before the call to the operation implementation on the server side.
The option comes in three varieties: {precond, {M, F}}
which activates the call for operations in all
interfaces in the source file, {{precond, IntfName}, {M, F}}
which activates the call for all operations in a
specific interface and {{precond, OpName}, {M, F}}
which activates the call for a specific operation.
The precondition function has the following signature
m:f(Module, Function, Args)
.
Example option: {precond, {mod, fun}}
adds the call
of m:f for all operations in the idl file.
Example options: [{{precond, "M1::I"}, {mod, fun}}]
adds the call of m:f
for all operations in the
interface M1::I1
.
Example options: [{{precond, "M1::I::Op"}, {mod, fun}}]
adds the call of m:f
for the operation
M1::I::Op
.
Adds a postcondition call after the call to the operation implementation on the server side.
The option comes in three varieties: {postcond, {M, F}}
which activates the call for operations in all
interfaces in the source file, {{postcond, IntfName}, {M, F}}
which activates the call for all operations in a
specific interface and {{postcond, OpName}, {M, F}}
which activates the call for a specific operation.
The postcondition function has the following signature
m:f(Module, Function, Args, Result)
.
Example option: {postcond, {mod, fun}}
adds the call
of m:f for all operations in the idl file.
Example options: [{{postcond, "M1::I"}, {mod, fun}}]
adds the call of m:f
for all operations in the
interface M1::I1
.
Example options: [{{postcond, "M1::I::Op"}, {mod, fun}}]
adds the call of m:f
for the operation
M1::I::Op
.
Warning options
The option activates all reasonable warning messages in analogy with the gcc -Wall option. Default value is true.
The maximum numbers of errors that can be detected before
the compiler gives up. The option can either have an integer
value or the atom infinity
. Default number is 10.
The maximum numbers of warnings that can be detected before
the compiler gives up. The option can either have an integer
value or the atom infinity
. Default value is
infinity.
Suppresses all warnings. Default value is false.
Warning appears whenever names are shadowed due to inheritance; for example, if a type name is redefined from a base interface. Note that it is illegal to overload operation and attribute names as this causes an error to be produced. Default value is true.
Activates all warning options. Default value is false.
Suppresses compiler printed output. Default value is false.
Back-End options
Which back-end IC will generate code for is determined by the supplied
{be,atom()}
option. If left out, erl_corba
is used.
Currently, IC support the following back-ends:
This option switches to the IDL generation for CORBA.
Generate CORBA call-back module templates for each interface in the target IDL file. Note, will overwrite existing files.
Will produce plain Erlang modules which contain functions that map to the corresponding interface functions on the input file.
This is an IDL to Erlang generic server generation option.
Will produce a C client to the generic Erlang server.
Will produce a C server switch with functionality of a generic Erlang server.
Will produce Java client stubs and server skeletons with functionality of a generic Erlang server.
Deprecated. Use c_client
instead.
Preprocessor
The IDL compiler allows several preprocessors to be used, the
Erlang IDL preprocessor
or other standard C
preprocessors.
Options can be used to provide extra flags such as include
directories to the preprocessor. The build in the Erlang IDL
preprocessor is used by default, but any standard C preprocessor
such as gcc
is adequate.
The preprocessor command is formed by appending the prepoc_cmd to the preproc_flags option and then appending the input IDL file name.
Configuration
The compiler can be configured in two ways:
-
Configuration file
-
Command line options
The configuration file is optional and overrides the compiler
defaults and is in turn overridden by the command line options.
The configuration file shall contain options in the form of
Erlang terms. The configuration file is read using
file:consult
.
An example of a configuration file, note the "." after each line.
{outdir, gen_dir}. {{impl, "M1::M2::object"}, "obj"}.
Output files
The compiler will produce output in several files depending on
scope declarations found in the IDL file. At most
three file types will be generated for each scope (including the top scope),
depending on the compiler back-end and the compiled interface.
Generally, the output per interface will be a header file (.hrl
/
.h
) and one or more Erlang/C files (.erl
/.c
).
Please look at the language mapping for each back-end for details.
There will be at least one set of files for an IDL file, for the file level scope. Modules and interfaces also have their own set of generated files.