|Allegro CL version 9.0|
Unrevised from 8.2 to 9.0.
This document contains the following sections:1.0 Delivery introduction
This document describes the application generation utility in Allegro CL. The facility differs from the image creation utility (see building-images.htm) in that the end result is not a single image file but a directory of files in theory suitable to be delivered to customers after suitable packaging.
generate-application and generate-executable are the functional entry point for developers to deliver an application. (Note that generate-application and generate-executable are only available in Enterprise versions of Allegro CL.)
On Windows when you use the Integrated Development Environment, much of the file handling and such is done using projects. When you have a project defined, you build an application using the IDE menu option File | Build Project Distribution (which calls generate-application on a project). In this document, we describe generate-application rather than the File | Build Project Distribution menu command, but what we say about generate-application broadly applies to building applications using projects (thus most of the subsections of Section 4.0 Creating the deliverable apply). See IDE User Guide, chapter 4: Projects for discussion of projects.
On Unix or on Windows without the IDE, the task of generate-application is to build and assemble the files for the developer's application into a single directory. This directory has many purposes. As a developer, you might want to:
For the purposes of this document, it does not matter what the motivation of the developer is, generate-application is used in the same way.
There are three distinct delivery types, as:
(1) is the most common case, by far. (3) is what is commonly called Lisp as a subroutine. (2) requires registration, either implicit or explicit. In the OLE samples there are examples of both.
It is important to understand that generate-application calls build-lisp-image and the latter starts a new (operating system) process to build the requested image. Any errors that occur during the building of the image will be handled in the other process. The development environment of the originating process (the one in which the call to generate-application was made) cannot be used to debug the problem in the image creating process.
See Debugging an image build problem or failure in building-images.htm for more information on debugging the image creating process.
If you want to distribute your applications outside your organization or inside your organization to users with machines not licensed to run Allegro CL, you must be licensed to do so by Franz Inc. One type of license that allows distribution is an Allegro Runtime license. See runtime.htm. Please contact your Franz Inc. account manager for information on licensing applications.
You need all the features necessary to run your application (whatever they may be). Certain items, like the debugger, the inspector, the tracer, will not be present in an image unless explicitly used or called for. If you are preparing a runtime delivery, be sure to check the Allegro CL runtime license to see what modules cannot be included in the image. See Section 3.6 Including all desired modules for information on insuring all needed and licensed functionality is included in the delivery image.
builds runtime images (see runtime.htm). The value
of the runtime keyword argument to generate-application (actually, it is a
accepted by generate-application) must be one of
:standard (the default),
:standard, the compiler cannot be in the final
image. You must either specify include-compiler
latter choice allows the compiler to be present during the build,
which is sometimes useful. The compiler may be included in a Dynamic
Allegro Runtime image (value of runtime
:dynamic) and in a Partner's Runtime
image (value of runtime
:partners). Partner's Runtime is
described in Allegro CL
Partner's Runtime in runtime.htm.
Allegro CL supports non-ASCII character sets and allows the specification of a locale that specifies the standard character set to be used. If the locale where the application being generated by generate-application is different from the locale on the machine where the application is generated, then the necessary code for switching external formats must be included in the image or available to the application. This is most easily done by specifying the runtime-bundle keyword argument true. See Locales in applications in iacl.htm.
Are your users going to interact with your application through the Lisp top-level (so they will enter Lisp forms or at least one Lisp form), through a custom top-level of your own, or will users interact with your application via some graphical user interface? (Of course, some applications may have no top-level -- that is, little or no user interaction is necessary.)
If your application has a custom top-level, you must write its
functionality and have it initiated when your application image
starts. You do this by having the function that is the value of
initiate your top-level. If your application has no top-level, then
the value of
*restart-app-function* should be the function
that starts your application running.
If you want to use the standard Lisp top-level, leave the value of
nil. Any initializations that
are necessary can be done by the function that is the value of
Warning for users calling generate-application from the IDE:
the value of
*restart-app-function* may be a function which
starts the IDE. That value will be inherited if the
restart-app-function keyword argument to generate-application (or build-lisp-image) is unspecified. Be
sure to specify it
nil if you want to use the
standard Lisp top-level, rather than leaving it unspecified.
A minimal top-level is provided if you build an image with the include-tpl argument to build-lisp-image (or generate-application, which accepts build-lisp-image arguments). See Minimal top levels in building-images.htm for more information.
In the past, it was possible to deliver an application as a single file (called a standalone application). This is no longer possible. We have, however, created a precise method to help you easily create and identify all the necessary parts of your application for it to be complete. generate-application is the entry point to creating your application. This function creates a directory containing all the files making up your application.
A standard Allegro CL image on startup does not contain all the system
modules that a program may invoke. Instead, certain modules are left
out (and contained in the bundle file, typically sys:files.bu
but the name varies, or in a fasl file in
sys:;code;, the code/ subdirectory of
the Allegro directory). When a module is called for with require, it is looked for according to
*require-search-list*, which usually looks
in sys:;code; and, if it is not there, in the bundle file
(which is essentially a collection of fasl files). Further,
when an important function associated with the facility is called
(e.g. trace for the trace
module, def-foreign-call for the foreign
module, etc.), the system detects that the module must be loaded and
loads it automatically (a process called autoloading, see Autoloading in
However, the bundle file supplied with the distribution, files.bu or whatever it is named, generally cannot be distributed with applications. (It is explicitly forbidden to distribute the bundle file, usually files.bu but the name varies, with a runtime image. If you have a VAR license, you may or may not be allowed to distribute the bundle file, depending on the terms of the license. In this document, we assume you are not permitted to distribute the bundle file. If you have any questions about licensing issues, please contact your Franz Inc. account manager. If you have an Allegro Runtime license, see runtime.htm)
There is, however, a bundle file specifically for a runtime
:runtime-bundle t in your call
to generate-application and
a files.bu will be created and placed in the application
directory. This file may be distributed with your application.
If you are creating an application on Windows using the IDE project system, there is a tool for finding necessary modules. See the description of the Find Required CG Modules button on the Project Manager Include Tab
Or you can ensure that all desired modules are loaded into the image. The remainder of this section describes how to do that in case you do not want to use the runtime bundle option.
The file sys:develenv.cl contains a list of require's that load optional functionality for the Lisp development environment. Some of the require's in this file are explicitly forbidden by your Allegro CL Runtime or Allegro CL Dynamic Runtime license agreements, and those are identified by comments. Do not modify that file but rather copy it or the desired parts of it to your own file for use with your own application.
You should require the modules you need for your application to work properly. Check the autoloads.out file generated when the autoload-warning keyword argument to generate-application is specified true (the default when generate-application is called). That will tell you what modules might be autoloaded in your application and you can decide whether it is necessary to include the module. (Just because a module might be autoloaded, that does not mean that it will be autoloaded in your application. Modules are typically autoloaded when an important function associated with the module is called. If your application does not call a function that triggers an autoload, the autoload won't occur.)
autoloads.out actually identifies the files that
will be autoloaded. A module name is the keyword symbol whose name is
the filename. Thus, the name of the module associated with the file
(require :acldns) causes the file
acldns.fasl to be loaded.
Note that the value of the autoload-warning argument can be a string naming a file (perhaps including directory information). If it is, the information will be written to that file rather than autoloads.out
If you determine a module which a function might autoload is not needed in your application, you should consider fmakunbound'ing the function, so calling it generates an undefined function error rather than a file not found error (in a runtime application with no bundle file, an error of some sort will be signaled when a function that triggers an autoload is called).
Look at the file sys:;src;aclstart.cl (that is, the file aclstart.cl in the src/ of the Allegro directory). It is the source for the startup routine used by Lisp (the function start-lisp-execution) along with the sources for some ancillary functionality. (Note that the low-level initialization, including mapping of .so/.dll files built with the image -- systems libraries and others -- has already been performed when start-lisp-execution is called. As with any UNIX or Windows program, failure to find a needed shared object or Library file (so/sl/dll) during the low-level startup causes immediate program failure usually accompanied by a terse message identifying the unfound file. list-all-foreign-libraries can be used to identify dependencies on .so, .sl and .dll files.)
Examining the source for start-lisp-execution will tell you the exact sequence of operations -- when the command-line arguments are processed, when the init files are read, etc., so you can know in what order to do things. The startup sequence is also given in startup.htm.
There are several places where a programmer can intervene in the
startup process. One relatively early place is the restart-actions
list (the value of
*restart-actions*). Please note that this list
may be used by Allegro CL or related functionality (such as
CLIM). Therefore, you should add to the list but do not remove items
from it or destroy it. Even earlier, -e command-line arguments are
processed (assuming command-line arguments are not ignored by the
image). Slightly later (but with a different interface), the
ACL_STARTUP_HOOK environment variable is examined. If it has a value,
that value is read by read-from-string and the result is evaluated.
The final two locations for programmer intervention in startup are the
functions which are the values of
*restart-app-function*. As you
may see from aclstart.cl (found in the
src/ subdirectory of the Allegro directory), if
true, it is assumed to name a function with no
arguments and that function is funcall'ed. The purpose of
excl:*restart-init-function* is to perform application initializations
of any sort.
*restart-init-function* completes, either
is funcall'ed (if it is
true) or a standard Lisp listener is started (but
not both). If your application has its own top-level, it should be
*restart-app-function*. (Or if no top-level is
*restart-app-function* would perform whatever
your application does.) Note that the function that is the value of
must not return. The consequences are undefined if it does return.
It is entirely your choice whether you use your own top-level or use the Lisp top-level. Note too that if you are using the normal top level, that is the image was built with the include-tpl argument to build-lisp-image true, you can start a Lisp top-level at any time by evaluating the following form:
(tpl:start-interactive-top-level *terminal-io* 'tpl:top-level-read-eval-print-loop nil)
Programmers who use a Lisp listener as a top-level often want the
current package (the value of
*package*) to be something other than the
common-lisp-user package when the user sees the
first prompt. Evaluating the following two forms as part of the
function that is the value of
*restart-init-function* accomplishes this
:my-package with the desired name, of
(tpl:setq-default *package* (find-package :my-package)) (rplacd (assoc 'tpl::*saved-package* tpl:*default-lisp-listener-bindings*) 'common-lisp:*package*)
The second form suppresses (on startup) the [changing package from
...] warning printed by Allegro CL when the value of
*package* is changed by the system in a Lisp listener
(usually printed when the debugger is entered).
All logical pathname translations (except the one for sys: set up in the low-level startup code) are cleared as one of the first actions of start-lisp-execution (indeed, the first form in the function definition):
(defun start-lisp-execution () ... (flush-all-logical-pathname-translations) ...)
This is often not what an application developer wants. However, it is a conscious choice because the potential for mysterious bugs resulting from bogus translations being present in the image outweighed the cost of re-establishing the translations when needed.
If you want to use logical pathname translations in your application, then you will need to arrange for them to be present. You can do this in one of two ways:
generate-application causes all .so/.dll/.sl files loaded during image creation to be copied to the directory it creates. It also arranges, upon image restart, for these files to be reloaded from this directory (which is what will become sys:).
It is possible to significantly speed up the initialization of CLOS-based applications by gathering information about CLOS usage in the application and including that information in the application image. In this section, we discuss what information is useful for this purpose, how to collect it, and how to include it in an image.
First, let us explain the issue. The initial way to create instances and find effective methods is inherantly slow and inefficient, but Allegro CL notes what is done and so subsequent similar invocations are much faster. Lisp will write specialized functions for certain tasks and will store patterns used for others. Therefore, CLOS performance speeds up significantly as an application runs. Because it is only the first specific invocation that is slow, this slowness does not have a significant effect on overall performace.
But there is a problem with delivery images without the compiler (and delivery images do not contain the compiler unless there are specially licensed to do so): the discriminator functions that are written while the delivery application is running cannot be compiled and so run imterpreted, which means run slowly. Also, it is useful to have any CLOS optimization information conveyed from the development image to the delivery image in order that the delivery image will run as fast as possible from the start.
The problem is, however, how to convey this information. The delivery image is built in a process spawned by the development imge (which calls generate-application). Only numbers and strings can be passed to the command that initiates the new image but the information we want to pass (such as compiled function objects) cannot be encoded in numbers or strings. So we need to have the development image produce a fasl file which will contain the desired information and have the delivery image load this file.
CLOS training provides a significant performance enhancement in delivery images. If you notice that your delivery image runs noticeably slower than your application in the development image, it may be because you do not have adequate CLOS training.
Note about the development environment: Lisp users typically run in developer-environment mode. In that mode, the debugger, the code that runs the Emacs-Lisp interface, Allegro Composer (if ordered) etc. is loaded into Lisp. Often your application will not use those facilities and your application images will not want to include them. However, CLOS training will include information about those utilities (and then require you to have them available when you build your application image) unless you do one of the following:
This is the less-desirable solution. You can create an image without the development environment by specifying
in the call to build-lisp-image. You can then train with that image.
This is the better choice. You will see forms like
below. If no packages are listed, the entire system (including
development environment features) will be trained. If packages are
listed, only things in those packages will be trained. Packages are
named by keywords. Typically, packages should include
:lisp, and the packages
of your application. Thus, if your application packages are
preload-constructors form would be
(excl::preload-constructors (:user :lisp :foo :bar))
The preload-generic-functions form would similarly list the packages.
A generic function examines its arguments to determine which method or methods are applicable. This is called discrimination. The symbol-function of a generic-function is a discriminator function. There are various kinds of discriminators and the discriminator for a particular generic function may change during the execution of a program.
When Lisp determines that a generic function needs a different kind of discriminator it checks to see if the one it needs has already been built and, if not, creates one. The creation of a discriminator is relatively expensive since it involves the Lisp compiler.
When a CLOS application is loaded the generic-functions all have a simple discriminator which will select the correct discriminator when the generic function is first called. Therefore when a CLOS application starts it will run very slowly unless the discriminators it needs are already built. The only way to tell which discriminators your program needs is to run your program for a while and then look at the list of discriminators that exist. Allegro CL provides a mechanism for dumping out these discriminators and then loading them in with your program so that when the program starts all the discriminators it will need will already exist.
You can dump discriminator functions to a fasl file by compiling a source file that contains the following two lines after loading and running your application (note that the best optimization is achieved if you combine this with the caching optimization described below):
(in-package :excl) (preload-forms)
With method-combination a call to a generic function can result in a sequence of methods being called. The code that calls the methods and processes the results of each call is called an effective method. In order to make effective methods fast, Lisp compiles them. In order to cut down on the compilation cost, Lisp actually creates effective-method templates which are functions closed over the particular methods to be called.
Thus many effective methods can share the same code. Just as in the case of discriminators above, it is expensive to start a CLOS application running if the effective methods it will need haven't been compiled already. And again Allegro CL provides a way of saving the effective methods that the application has used so that they can be defined before the application starts.
You can dump effective methods to a fasl file by compiling a source file that contains the following two lines after loading and running your application (this is the same as for discriminator functions):
(in-package :excl) (preload-forms)
Generic functions use caching to implement fast dispatching. When an application starts the caches are empty so initial performance is degraded by having to handle cache misses. Allegro CL provides a way to fill the caches when an image starts up.
You can dump caches to a fasl file by compiling a source file that contains the following two lines after loading and running your application (see above under the heading Note about the development environment for information on ([packages]) in the following form):
(in-package :clos) (excl::precache-generic-functions ([packages]))
As we describe briefly below, calls to make-instance can be replaced with calls to some equivalent (but much faster) constructor functions. Allegro CL provides a way to preload compiled constructor functions.
You can dump constructors to a fasl file by compiling a source file that contains the following two lines after loading and running your application (see above under the heading Note about the development environment for information on ([packages]) in the following form):
(in-package :clos) (excl::preload-constructors ([packages]))
Suppose those two lines are in a file named
myclosopt.cl. Compile that file with a form like
(compile-file "myclosopt.cl") to produce
myclosopt.fasl. (You may use any filename, of
course. We use a filename here so we can refer to the
fasl file below.) This file must be loaded into
an image being built after all the relevant make-instance calls
are loaded. This can be guaranteed be loading the constructor file
When you are generating an application with generate-application and you use this method
to speed up constructor functions, you must include the module
:constructor before the fasl
file that that contains the above call to preload-constructors
(myclosopt.fasl in our example). These files and
modules are typically in the list which is the value of the
input-files argument to generate-application (the third required
argument). Again, if the fasl file is named
myclosopt.fasl, the value of
input-files should be something like (as the use
of suspension points indicate, we are loading myclosopt.fasl last, as
'(... :constructor ... myclosopt.fasl)
Of course, you may have some other way of specifying files and modules (so, for example, the input-files list contains one file which contains the loads and requires for your application. In that case as well, the :constructor must be required before the myclosopt.fasl is loaded.
In this example, we create the constructor file during the image
build. Note we load it last, as that ensures it will have maximum
effect. If it is loaded earlier than a relevant call
to make-instance, optimization may not occur. We have a call to
(main) and the defined main function is very
simple, but in an actual application, it could do much more work if
cl-user(1): (shell "cat closopt-example.cl") (in-package :cl-user) (defclass foo () ((base :accessor base :initarg :base) (val :accessor val :initarg :val))) (defun main (&rest args) (do-test) ) (defun do-test () (loop for i from 0 to 3 as data = (make-instance 'foo :base i :val (* i i)) sum (val data)) (dotimes (i 10) (time (loop for i from 0 to 200000 as data = (make-instance 'foo :base i :val (* i i)) sum (val data))))) (defun build () (with-open-file (st "closopt-example-pre.cl" :direction :output :if-exists :supersede) (format st "(preload-forms)~%") (format st "(excl::preload-constructors (list :cl-user :lisp))~%") (format st "(excl::precache-generic-functions (list :cl-user :lisp))")) (main) (compile-file "closopt-example-pre.cl") (generate-executable "sample" '(:trace :constructor :foreign "closopt-example.fasl" "closopt-example-pre.fasl") :allow-existing-directory t :include-compiler t :discard-compiler t )) 0 cl-user(2): :cl closopt-example ;;; Compiling file closopt-example.cl ;;; Writing fasl file closopt-example.fasl ;;; Fasl write complete ; Fast loading closopt-example.fasl cl-user(3): (build)
The four possible start-up optimizations were just described. Conveniently, two (discrimination and effective methods) are achieved with the same utility. All depend on information being available. Therefore, the following is the first step for all optimizations:
Once you have exercised your application sufficiently, you are ready to create the optimizing files. This is a standard fasl file created by compiling a special source file (described below).
(in-package :excl) (preload-forms) (excl::preload-constructors ([packages])) (excl::precache-generic-functions ([packages]))
Compile closopt.cl with compile-file. Lisp will put the discriminators,
the effective methods, the constructors, and the contents of its CLOS
caches into the resulting fasl file (closopt.fasl). If that file is
built into the application binary image (it should be specified as one
:lisp-files in a call to build-lisp-image, as an input-file in
a call to generate-application, or required by another
file specified in either location), then an application using CLOS
will start up significantly faster.
Note that loading this file will not invoke the compiler so this can be loaded into a compilerless Lisp.
We have already discussed dumping make-instance constructor functions. Note that calls to make-instance where the value of the class argument is a quoted constant and each of the keywords is a constant are transformed by the compiler into calls to constructor functions. A constructor function is a piece of code that is equivalent to the make-instance call except that it is significantly (10 to 100 times) faster.
The optimization is automatic when the call to make-instance is formed in a particular way.
In order for an optimized constructor function to be used certain restrictions apply:
|Generic Function:||Condition for optimization:|
|make-instance||Only system-supplied methods are applicable|
|initialize-instance||Only system-supplied-standard methods and user-supplied :after methods are applicable|
|shared-initialize||Only system-supplied-standard methods and user-supplied :after methods are applicable|
Conditions for creation of constructor functions: The calls to make-instance are replaced by calls to the constructor regardless of whether an optimized constructor can be used. The first time the constructor function is called, the system tests whether any of the restrictions apply. If none do, an optimized constructor is generated. When the restrictions are not obeyed, a non-optimized constructor function is created. It calls make-instance. Redefining a class or one of its superclasses or adding/removing a method to one of the generic functions mentioned above causes the constructor function to be recomputed.
As stated above, generate-application assembles the files needed to deliver an application. generate-application both builds the application's image file and copies any other files needed to support this image.
Like many powerful Lisp functions, generate-application has many options and can do many things, but quite a lot can be done with simple calls. For example, the following call builds an application from foo.fasl into the directory myappdir/ (relative to the current working directory of the running Lisp). You could then execute myappdir/myapp after the above form is evaluated.
(generate-application "myapp" "myappdir/" '("foo.fasl") :include-compiler nil)
generate-executable provides a simpler interface for generating applications.
generate-application is basically a wrapper around build-lisp-image. generate-application sets things up for producing a directory suitable for delivery and then calls build-lisp-image, which creates the actual deliverable image file. See building-images.htm for information on build-lisp-image.
build-lisp-image, and therefore generate-application, create a new image by starting a new Lisp process and having it load necessary files and then dump a final image. It is important to understand that the new Lisp process that does the work does not inherit anything from the Lisp process that spawns it. The arguments to generate-application and build-lisp-image specify details of the new image to be created, but outside the arguments, nothing is inherited (although some arguments do default to current values in the calling image). Thus, for example, if a user-defined function or package or variable or class is defined in the calling image, it will not be defined in the new image. Every aspect of the new image is defined by the arguments to generate-application and build-lisp-image or by the files loaded during the build process.
There is an example showing how to create an application in examples/testapp/. It is more complex than the one above, but still relatively simple. See readme.txt in that directory for information on the example, which is designed to show how to package an application. The code in the examples/testapp/ directory can be freely used. (Note that on Windows, you need the GNU make facility to use the example. The GNU make facility is (at the time of writing) available for free from http://sources.redhat.com/cygwin/.)
The definition of generate-application is:
(generate-application application-name destination-directory input-files &key allow-existing-directory application-administration application-files (application-type :exe) (autoload-warning t) (copy-shared-libraries t) (copy-file-function 'sys:copy-file) debug icon-file demo image-only pure-files purify runtime-bundle ...build-lisp-image keyword args... dumplisp keyword argument ignore-command-line-arguments...)
A string which is the name of the application (e.g.,
The name of a
non-existent directory (the directory can exist if the
A list specifying files to be loaded into the application. The
contents can be strings or pathnames naming Lisp
(.fasl or .cl) files or
keywords naming modules to be loaded with require. Note: this argument is passed to
build-lisp-image as the
value of the
A boolean. If true, allows the
destination-directory to exist. If the value of
this keyword argument is
|:application-files||A list of files (strings or pathnames) which should merely be copied to the destination directory.|
This argument allows the specification of various application
administrative tasks. The form of the value of this keyword argument
This creates a lisprc in the destination directory which sets the default command line arguments to "arg1" "arg2" "arg3" .... See the Section 4.1 Resources section below for more information. The Wondows version also supports win:set-default-command-line-arguments for the same purpose.
On Windows, the value can also be:
This creates either a batch file or a shortcut named
filename that will initialize the application. For a
shortcut, the filename must have type "lnk" (the letter L, the letter
N, the letter K). command line arguments are the arguments
to application-name.exe. The filename argument
should actually be a format control string given one argument, the
name of the application. It is used like this:
One use of this is for OLE registration. For example:
'(:shortcut "One-time registration of ~a" "-register")
If the given
foo.exe -- -register
An error is signaled if
A keyword specifying the application type. Valid values:
A boolean whose value can be string naming a file. When
true, the file autoloads.out is created
that contains the functions, macros and methods that could possibly be
autoloaded. Defaults to
This is a build-lisp-image
keyword argument but is also used by generate-application if a value is
supplied. The value must name a Lisp executable file (such as "mlisp"
on Unix or "mlisp.exe" on Windows). It is used by build-lisp-image to start the Lisp process
that builds the image. Unless image-only is true, generate-application copies a Lisp
executable to the application directory. The executable specified as
the value of this argument is the one copied.
See the description of this argument in building-images.htm for information on when it is useful: a value is specified either when a custom executable has been built (see main.htm) or when you want a character size in the new image that is different from the character size in the running image. On this last point, see The character size in the resulting image in building-images.htm.
A boolean. The value may be a lambda expression. If
true, then copy shared objects/libraries that
have been loaded with the Common Lisp function load, with the
system-library keyword argument
The value of this keyword argument can also be a lambda expression
(you cannot use the
|:copy-file-function||If specified, the value should be a function object or a symbol naming a function. This function will be used to copy files to the destination directory. The default value is copy-file and that function is likely sufficient for most purposes. However, another function can be used if that is insufficient. This function will be called by the image that calls generate-application (not the image that builds the image). If the default is used, all keyword arguments to copy-file are called with their default values. It is simple to write your own function which calls copy-file with other argument values, if desired.|
You can also avoid copying locales if you know which specific locales
an application needs. Instead of constructing a copy function for
generate-application, it is simpler to include those locales in
the application. Each locale is small, about 10K, so there is hardly
any space savings in leaving the locales unloaded. Locales are
inlcuded by having a file loaded by the application which contains
top-level forms of the type
;; file to cause specified locales to be loaded into an application (in-package :user) (find-locale "en_US") ; English in the USA (find-locale "ja_JP") ; Japanese in Japan (find-locale "fr_FR@euro") ; French in France using Euro currency (find-locale "fr_BE@euro") ; French in Belgium using Euro currency ;; end of file
When you are unable to anticipate locale usage at runtime, the safest thing is simply to copy the entire directory and let the application autoload.
|:debug||A boolean. If true, more information will be printed about progress as an aid to debugging.|
[Windows only, ignored on UNIX.] If specified, the value must be a
valid Windows .ico icon file. On the NT branch (which includes
win2000 and XP), any .ico file should work. See
Section 4.9.2 Icon files suitable as a value for icon-file for more information on
suitable icon files.
If a non-nil value is specified, win:set-application-icon is called to embed the icon in the exe file.
You must be licensed to produce
demos (demonstration applications) to specify a non-
|:image-only||A boolean. If true, just build the image, and possibly the .pll file.|
|:pure-files||The value should be a list of .cvs and .str files to be put into the application's .pll file. See Creating and using pll files in miscellaneous.htm.|
|:purify||A boolean. If true, do automatic purification of Lisp and the application. This means all the strings and code vectors will be put into a .pll file. If you choose this option, do not also specify a value for :pure-files.|
A boolean, default is
|build-lisp-image keyword args||
generate-application accepts and
passes through to build-lisp-image all of
|dumplisp ignore-command-line-arguments keyword arg||
generate-application accepts and
passes through to dumplisp
the ignore-command-line-arguments keyword
argument. When true, the resulting image will ignore command-line
arguments prefixed by a dash (
Resources are a way to specify default information for an application. The most common of which is command line arguments.
Resources are stored in a plain text file. This file, sys:lisprc, if it exists can contain resource information for application startup. Currently, this is just command line arguments. The format of lisprc is:.command-line: command line args...
orappname.command-line: command line args...
where appname is the name of the Lisp executable used to start Lisp and command line args... are a list of valid command line arguments. appname should be used when there are multiple applications sharing the same directory and different command line argument resources are needed for each application.
For example, a sys:lisprc of.command-line: -Q
would cause all applications in the directory this appears to start up quietly.
If there are both command line arguments in the resource file and given on the command line that starts the application, then command line arguments seen by the application are the concatenation of the resource command line and the given command line. This allows the given command line to override the resource command line.
The newly exported function windows:set-default-command-line-arguments also allows specifying the command-line arguments in an executable. Allegro CL executables come in two flavors on each platform: an 8-bit character version (for example alisp8.exe on Windows) and a 16-bit character version (for example alisp.exe on Windows). All Allegro CL executables (which, following standard Windows practice, have type exe) are copies of one or the other of alisp8.exe and alisp.exe. You can use windows:set-default-command-line-arguments to specify the command-line arguments for any such executable.
The Version Info of a file on Windows is information stored in the file and available to various Windows utilities. It is used for displayed information about the file. Allegro CL supports accessing and modifying the Version Info, using the functions win:file-version-info and win:set-file-version-info. An Allegro CL executable will work the same as an executable when the Version Info is changed, that is it will start Lisp with an appropriate image file. generate-application supports specifying the Version Info for the executable in an application directory.
If the application is made up of many source files, then using the defsystem utility (described in defsystem.htm) will help the management (for compilation and loading) of the application. If defsystem is used, then it is easy, for example, to create a single .fasl file representing the compiled application. See defsystem.htm and the function concatenate-system for more information.
The application should be optimized. Allegro CL contains space and time runtime analyzers that should be used to find places in the application which can be optimized. See runtime-analyzer.htm. The optimization of Common Lisp source code has two components, aside from optimizing algorithms used in the application:
Both of the above can be done globally or locally to a particular
function. Functions which are known to be used frequently should be
optimized by declaring the types of the values bound to symbols, when
the types are known and checked. Then, increasing the speed
compilation quality and decreasing the safety and debug qualities will
allow the compiler to produce smaller and faster code. These issues
are discussed in compiling.htm. Note particularly
:explain declaration discussed in that document, in
declarations: the :explain
If the application will not use the development environment of Allegro CL, then certain features of it can be turned off or compiled out of the application. For example, you might use the following global proclamation:
(proclaim '(optimize (debug 0)))
It will cause the compiler to compile with no consideration for easy debugging (presumably your users will not debug your application). Currently, this means local names of variables and the argument list for functions and macros will not be saved. Although the saving is not great, if these features are not to be used, then there is no reason to have the compiler annotate the fasl files with them.
Another saving can be achieved by evaluating:
(setf (argument-saving) nil)
This will cause the runtime calling sequence to be more efficient on some architectures (RS/6000 currently).
Setting of GC parameters and switches appropriate to application-specific behavior is important for performance. gc.htm contains a complete discussion of the subject, and the only information included here is a check-list of items to consider.
If keeping newspace small so that scavenges are short is important, then this feature should be enabled. One negative aspect of this, however, is that garbage collections will be more frequent and this may cause more short-lived objects to be tenured, resulting in faster growth of the Allegro CL memory image. You should schedule global garbage collections more frequently to keep the image smaller if you set :clip-new to t.
The users of many applications will not want to see the gc messages. Keeping this switch
nilwill prevent them from being printed. On the other hand, the gc message does explain why your application seems to have paused (during a gc). See also the discussion of gc cursors below.
:generation-spread (default: 4)
Depending on the behavior of the application, changing the generation spread may cause less garbage to be tenured. The default value has been chosen for development but not the runtime environment of applications.
:free-bytes-new-other (default: 131072)
:free-percent-new (default: 25)
:free-bytes-new-pages (default: 131072)
:expansion-free-percent-new (default: 35)
:quantum (default: 32)
These parameters determine the size of newspace after a scavenge. There must be at least :free-bytes-new-pages + :free-bytes-new-other bytes free, in addition to there being at least :free-percent-new percent of newspace free. :quantum specifies the number of pages (8k each) for newly created newspaces. The initial value is 32 for 256kb newspaces. :expansion-free-percent-new specifies the percent free in newly created newspaces.
:expansion-free-percent-old (default: 35)
This specifies how much must be free in an oldspace after it is created. A new oldspace is created because there is some amount of data that needs to be tenured and there is no current oldspace that can hold it.
See gc.htm for more information on memory layout.
A gc cursor facility provides some visual clue to the user that a garbage collection is taking place. Application writers find gc cursors useful since their users may think the application has hung while in fact it is just gc'ing. Unfortunately, implementing a gc cursor is difficult. See Gc cursors in gc.htm for more information.
In addition to the above parameters and switches, the variable
determines whether or not a global gc is automatically performed when
a certain number of bytes have been tenured (moved into
*tenured-bytes-limit* specifies this limit. It
is very important to note that an interactive application would have
execution suspended for an indeterminate amount of time if a global gc
is performed--scavenges are normally quite short, in comparison.
The initial values for the above parameters are reasonable defaults, but there may be better defaults for individual applications. See gc.htm for more information.
In 7.0, the Allegro Presto facility has been removed. See The Allegro Presto facility has been removed in loading.htm for further information.
Allegro Runtime is a Franz Inc. product which licenses distribution of
applications written in Allegro CL. Please contact your Franz
Inc. account manager if you want more information on Allegro Runtime
and its terms. See the document runtime.htm for
technical details of Allegro Runtime, including a list of restrictions
on runtime images. generate-application only produces runtime
images. The runtime defaults to
:standard and must be either
:partners. See runtime.htm for
The file msvcrt.dll is needed by all Allegro CL applications generated on Windows. If the copy-shared-libraries argument is true, generate-application copies all needed system DLL's to a subdirectory of the destination-directory called system-dlls. When your application is installed, these DLL's should be copied to the Windows system directory if necessary (i.e. if they are not already there with the same or a later version). In the system-dlls subdirectory, they will not be seen by your application or any other program.
These system DLL's have presented a problem for Allegro CL applications. They are needed if the application is to run successfully but having them in more than one location where Windows sees them can create difficulties. Therefore, they cannot be put in the destination-directory, for that might result in two copies being visible (one there and one in the Windows system directory). And they cannot be copied blindly to the Windows system directory because that might overwrite an existing copy and result in a version mismatch (since other programs that depend on the copied-over later version may then fail).
We have tried to mitigate this problem by providing an install wizard (described in section Section 4.10 Installation of your application on Windows using the Install Wizard below) that does the right thing: it finds out if the DLL files in the system-dlls subdirectory are in the Windows system directory already. Any that are not are copied to the Windows system directory. The versions of the ones that are present are compared to the versions of the files in system-dlls. Earlier versions are then updated (more precisely, are either then updated or things are arranged so they will be updated when Windows is restarted, so other running programs will not be affected).
Note that DLL's loaded with load with
:system-library specified as true (see Using the load
function in loading.htm) are not copied
to destination-directory or the system-dlls
subdirectory. The only files that are copied to the
system-dlls subdirectory are mfc42.dll and
msvcrt.dll. (This may seem counter-intuitive, but we feel
free to copy mfc42.dll and msvcrt.dll because
Microsoft explicitly allows it.)
Autorun options. On a different subject, it is possible to have a program autorun (that is, started automatically when, for example, a CD containing the software is inserted into the CD drive). See the MicroSoft document http://msdn.microsoft.com/library/psdk/shellcc/shell/Shell_basics/Autoplay_cmds.htm for useful information.
If your application is started so the console window is created
+c command-line argument -- no console --
was not specified on the command line), the function console-control provides control over
whether the tray icon and/or the console window is visible, and
whether you can exit the application using the tray icon and the close
button on the console. The method close-console also provides control
over the actions of the close button on the console (and the Alt-F4
key combination and the Exit choice on the tray icon menu).
The value of the icon-file to generate-application, if
nil, must be a valid Windows icon file
containing the icon that will be used for the application (in place of
the bust of Franz Liszt icon used by Allegro CL). Such files normally
have the .ico file type. A
.bmp pixmap file or other non-icon image file
will not work as an application icon.
If you are unfamiliar with console apps, you probably do not want to create one.
Console apps should not use multiprocessing nor excl:run-shell-command (in any form, which means do not use excl:shell or any of the subprocess API in excl.osi -- os-interface.htm). Doing so can cause the console app to hang. The problem has to do with I/O and the Windows console API and is a current Allegro CL restriction.
With that in mind, create a colsole app as follows:
(progn (delete-file "dist/app.exe") (sys:copy-file #+ics "sys;buildi.exe" #-ics "sys;build.exe" "dist/app.exe"))
In the application, using format to
*terminal-io* will result in the output going to
the console command window.
On Windows, the Lisp executable file is name [something].exe, where something is alisp, mlisp, allegro, alisp8, or mlisp8. When the application is created, a copy of the appropriate executable is made and put in the application directory with the name changed to be the application name.
Executables on Windows store information about the application in VERSIONINFO slots. The function file-version-info returns a list of alternating keywords and values:
cl-user(5): (pprint (windows:file-version-info "lisp.exe")) (:comments (128 "") :company-name (138 "Franz Inc.") :file-description (148 "Allegro Common Lisp.") :file-version (136 "188.8.131.52") :internal-name (136 "lisp.exe") :legal-copyright (154 "Copyright 2009, Franz Inc.") :original-filename (136 "lisp.exe") :product-name (147 "Allegro Common Lisp") :product-version (136 "184.108.40.206") :language-id 1033 :language-name "English (United States)" :code-page 1252) cl-user(6):
generate-application has a keyword argument file-version-info. Anything keyword in return value of file-version-info that has a value which is a cons is a valid value to be used in the list passed as the value of that argument. The VERSIONINFO in the copy of the executable file placed in the application directory will have the specified values in the fields which are specified. Here is an example:
(generate-application "foo" "foo/" nil :include-compiler nil :file-version-info '(:company-name "Foo Inc" :product-name "Foo Bar" :legal-copyright "Copyright (C) 2009 Foo, Inc." :product-version "220.127.116.11"))
The executable will work just like any Allegro CL executable: when passed an appropriate image file as an argument, it will execute that image file. The VERSIONINFO does not affect the execution of executables. It does affect information displayed about the executables as discussed in Windows documentation.
The Allegro CL Install Wizard is a tool that application programmers writing Allegro CL-based applications can use to help deliver applications on the Windows platform. It is designed to deal with the problem of ensuring that system DLL's supplied with the application distribution are installed if necessary, but are not installed if a later version is already present. Note that the Install Wizard is a bare bones installer and is not meant to compete in the Windows installer market. We recommend the Install Wizard for only the simplest of installations. If your needs are anything beyond the bare bones, please consider using a commercially available installation program. We list some with which we are familiar next:
In accordance with your license agreement, you can distribute Allegro CL-based applications. The files in the directory described in `1. Create the initial application directory' below are typically suitable for distribution, but again, this is controlled by your license. Ask your Franz Inc. account manager for information on what your license allows if you are unsure. We assume in the remainder of this section those files are licensed for distribution.
Reasons for providing the Install Wizard. You can create a delivery directory, either with generate-application or the IDE's File | Build Project Distribution menu command. On Windows, this directory includes a system-dlls/ subdirectory. System DLL's needed for the application, such as mfc42.dll and msvcrt.dll, are placed in that directory.
As described in section Section 4.9 Windows specific information, there is a problem when you install your application on a customer's machine: you must ensure the right thing is done with the system DLL's. They should be installed on the customer's machine if necessary but should not be installed if not necessary. So, it must be determined whether such installation is necessary. Further, when installing on Windows, various bookkeeping tasks like updating the registry must be performed. A program, usually named setup.exe, is typically provided to perform such tasks. The Install Wizard generates an appropriate setup.exe. Note: the user installing the application must have administrator privileges on Windows NT and Windows 2000.
Here are the steps for using the Install Wizard. Note that the Install Wizard will ensure that the user doing the installation has the administrative privileges necessary to install the application.
Use either generate-application or the IDE's File | Build Project Distribution to create a directory, which for example purposes we will call c:/foo/foo/. This will be a directory of files and subdirectories. This directory is named by the destination-directory argument to generate-application and by the Distribution directory dialog when using the Build Project Distribution menu command.
When generate-application or Build Project Distribution complete, you now have the initial application directory.
Run the Install Wizard via a shortcut on the Start | Programs | Allegro CL submenu. This will display the Install Build Wizard dialog, which has the following fields:
The Install Wizard will create a new directory (called the Output directory) and copy the files from the source directory to it. Further, it will generate a program named setup.exe and put it in the output directory.
The following buttons are on the bottom of the dialog: Build, Quit and Help. After filling in the fields, click on the Build button to create the directory specified in Output directory. Quit will exit without building anything. Clicking on Help displays this section of this document in a browser.
When the Install Wizard completes, the output directory is suitable for distributing to application users. We assume it is placed on a CD. How the CD is organized is up to you, the application writer. We assume the CD contains a single directory distdir/ which contains the contents of the output directory from above. (At the toplevel, it may have a file causing it to autorun when the CD is inserted into the drive. In any case, setup.exe must be in the same location with respect to all other files as it was in the output directory.) Note, this will work equally well if you are distributing on floppies or some other media.
Once you have the CD, then you as application developer have finished creating the distribution.
The application user (presumably your customer) receives the application CD and puts it into the CD drive. On the application user's machine, there is (presumably) no Allegro CL, and the source and output directories mentioned in 2 above do not exist either. Recall we assume the CD contains a single directory distdir/ which contains the contents of the output directory from 2 above. That directory includes the installation program setup.exe. To run setup.exe on Windows NT and 2000, the user must have administrator privileges.
When the application user runs setup.exe (in our example, by inserting the CD into the drive and running distdir/setup.exe), setup.exe will ask the user for an installation directory for the application, which we will call appdir. This directory must not exist. setup.exe will create the directory and install the application. Specifically, setup.exe will do the following:
If at any time the installation program gets an error, it will undo any changes made to the disk containing appdir and to the Windows registry. That is, if the application does not install, then appdir will not exist and no application files will be left on the user's machine, and the registry will be left in the pre-installation state.
Part of the installation process done by the Install Wizard on an application user machine is the creation of an uninstallation program and the addition of appropriate entries in the registry having to do with uninstalling the application. An uninstall/ subdirectory is placed in the application directory. It contains the programs necessary for uninstallation.
Uninstallation of the application must be done using the Add/Remove Progams control, which can be displayed using the Windows Control Panel. User should not directly run the programs in the uninstall/ directory.
It is best to test an application on a different machine from the one it was developed on, as this ensures that machine-specific dependencies (presence of system libraries, for example) are better controlled for. However, even testing on the same machine can provide useful information. Because most necessary files are in the application directory, even after installation, the machine dependency problem is reduced. (Note that on Windows, Allegro CL DLL's are installed in system directories so you must be sure that the application is not working just because the ones from the Allegro CL installation are present.)
Evaluation copies of Allegro CL have a built-in expiration date (paid-up licensed copies do not have an expiration date). Applications built from evaluation copies will display the following when started:
WARNING: !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! WARNING: Application will expire on [date] (XXX days). WARNING: !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
where [date] is a specific date in the future and `XXX' is the number of days until expiration. If you believe you have a paid-up, licensed copy of Allegro CL and you see that warning when your application starts, please contact Franz Inc. for advice, since such a warning should not appear. (Submit a bug report as described in Reporting bugs in introduction.htm.)
The function generate-executable is a wrapper for generate-application, producing an application whose input is the command-line arguments. It can be used either as a quick way to create an application, or as an example of using generate-application. The source for generate-executable can be found in the file [allegro-cl-dir]/src/genexe.cl.
There may be bugs in the version of Allegro CL used to deliver your application and there may be bugs in your application code. Both need to be fixed for your users. Allegro CL bugs are typically fixed by patches supplied by Franz Inc. You, of course, have to decide how to provide fixes for bugs in your application, but you may wish to mimic the patch system used by Allegro CL. That system and the tools associated with it are the subject of this section.
The following two features are useful in a patch system:
The tools provided support both features. The tools are the defpatch macro, the load-patches function, and the featurep predicate function.
We first describe the Allegro CL patch scheme and then discuss how you can adapt it to your application's needs. Allegro CL patch files are named as follows:
So the first letter is p, followed by
The version ([m]) changes with each new release. Its value is the
example, pca001.001 is the first version of the first patch
file on version 9 (Allegro CL 8.0) for product
CL base Lisp). pca001.002 is the second version of the first
patch file. pca011.002 is the second version of the eleventh patch
All Allegro CL patches are placed in one directory, sys:;update, that is the update subdirectory of the Allegro directory, where Allegro CL was installed.
Patches are loaded by load-patches. It takes only keyword arguments and the arguments are:
|update-directory||The directory in which to look for patch files. Defaults to the Allegro CL patch directory, sys:;update.|
|product||Value should be
|patch-file-filter||A function of three arguments, a product code, a pathname, and a version ([m] above). Returns true if the pathname names a valid patch file (based on parsing the name and location only).|
|patch-file-sorter||A function of three arguments, a product, a list of patch files (validated by the patch-file-filter), and a version ([m] above). Sorts the list into the order in which the files should be loaded (from highest version to lowest).|
|version||Specifies the version ([m]
Should be a character object
naming a decimal digit (#\0 - #\9) or a lowercase
alphabetic letter (#\a-#\z). This is for use with
application patches only.
Defaults to the value of
You should have an update/ subdirectory to your application directory (or wherever sys: translates to in your application). Then you can distribute post-loadable Allegro CL patches file to customers. post-loadable means that the patch can be loaded into an existing image. However, not all Allegro CL patches are post-loadable. You must distribute a new image with patches loaded if you need to deliver a non-post-loadable Allegro CL patch to your customers.
Patches are loaded latest version first and earlier versions are only loaded if the later version fails for some reason.
The easiest way to provide loadable patches to your own application
is to have a separate directory (say sys:;myapp-update) where
your patches will go. Then mimic the Allegro CL patch naming scheme
and call load-patches,
specifying update-directory to be the directory you
chose. load-patches should
be called when your application starts up. As long as your patch files
are created with sys:defpatch, the scheme should work with
your application. Make sure that the version ([m] parameter) is the
excl::*cl-patch-version-char* for the
version of Allegro CL you are using.
If you want to use a different naming scheme, you will have to supply your own patch-file-filter and patch-file-sorter functions. See the description of sys:load-patches for advice on how to do that.
Again, please do not mix your application patch files with Allegro CL patch files in the same directory (unless you use your own naming scheme that cannot be confused with the Allegro CL naming scheme, and even then it is a bad idea). Franz Inc. reserves the right to use any product code at any time and so you cannot guarantee the uniqueness of filenames simply by using an apparently unused product code.
The value of the variable
sys:*patches* is a list of loaded patches.
The following table describes the three attributes of patch files.
|post-loadable||Can be loaded into a running image (so named because loadable after -- post -- the original image build).|
|superseded||This attribute is no longer used. Since the latest version of a patch is loaded (and if it cannot be loaded, the next latest, and so on), a superseded version is not looked at. Therefore this attribute is not necessary.|
A patch file is a compiled Lisp file. At the start of the patch file, there should be a sys:defpatch form, followed by the code that implements the patch. Therefore, a skeleton patch file will look like the following:
;; Our application ;; patch for report XXXX (sys:defpatch "mpnnn" 1 ;; replace mpnnn with the product version (m), ;; product code (p), the patch id number (nnn) and ;; 1 with the patch version "MESSAGE" ;; Brief patch information (should fit on one line) :type :myapp ;; Type should be a keyword of your choosing. ;; Other arguments may be specified. ) ;; Put patch code after here ... (in-package :blah)
The required arguments to sys:defpatch are:
A string identifying the patch number or name. This is usually the [m][p][nnn] of the patch file name and typically includes zero-filled numeric characters -- e.g. "0a001", "1j195", "0z234" -- but can include alphabetic characters and need not be exactly five characters long. It is not the patch file prefix. This id is unique to the patch.
A fixnum in the range 1 to 999 inclusive. This is the [v] of the patch file name.
A string containing a brief description of the patch. Short strings are better because this string is printed by dribble-bug when it reports information of patches and long strings may mess up the printing (by forcing line wraps). Example "Fixes filename bug" or "Speeds up processing employee info".
The keyword arguments to sys:defpatch are:
A keyword specifying the type of the patch. Default is
:unknown. Application programmers should decide on a single type or a group of types for their application and classify their patches according to that scheme. When information on patches in an image is printed by dribble-bug, they are organized by type. The following types are reserved by Allegro CL and should not be used by application programmers:
:allegro*(any keyword starting with :allegro).
Default is 1. If a new version of sys:defpatch is supplied by Franz Inc., the default will be changed and patches with the old version will be rejected. In general, do not worry about this argument unless a new version of sys:defpatch is distributed (that distribution will include additional instructions).
t, the patch file can be loaded into a running image. When
nil, the patch file can only be included in an image during image creation with build-lisp-image. The patch load will abort if load-patches tries to load it into a running image.
nil. When true, value can be any form acceptable as an argument to featurep. If featurep returns
nilwhen applied to the form, the patch loading is aborted. The reason for aborting printed by the system is the form that is the value of this argument (made into a string).
nil. When true, value can be any form acceptable as an argument to featurep.
The compile-feature keyword argument is designed to facilitate producing patches for different platforms. For example, suppose a patch is only applicable to versions of Allegro CL that use os-threads for multiprocessing. Specifying
:os-threadsas the value of compile-feature will cause compilation to proceed when compiled by a platform that uses OS threads but to abort when compiled by a non-os-threads Allegro CL. Aborting is what you want in that case, since the patch is not needed for such platforms. The aborting of compilation will signal a condition which looks for a
sys::abort-patch-compilingrestart. If that restart is not present, an error is signaled (and the programmer must intervene to do something). More typically, compilation of patch files are done in a form like the following:(dolist (x patch-files) (restart-case (compile-file x) (sys::abort-patch-compiling (patch) ;; Actions of your choice, e.g printing a message like: (format t "Aborted patch file ~s, featurep returned nil" x))))
Compilation of the remaining patch files will continue and all relevant patch fasl files will be present when the dolist form completes.
How you and your application team will manage patch files depends on how you deliver your application and whether or not your customers can build new images with build-lisp-image. Only customers of properly licensed VARs and customers who hold an appropriate license from Franz Inc. for Allegro CL will be able to build new images. Customers (of yours) who receive runtime images (and are not independently licensed by Franz Inc.) cannot make new original images because dumplisp (called by build-lisp-image) does not work in runtime images.
This is an issue because (1) patches which are not post-loadable (i.e. cannot be loaded into a running Lisp) can only be included in a new original image; and (2) post-loadable patches can be loaded into a running image but should not be loaded into an image which already contains them. Therefore, if you have runtime customers (who cannot build original images), you can send them post-loadable patches and arrange for those to be loaded automatically, but you may also send them new images from time to time (which include non-post-loadable patches but will usually include all available post-loadable patches as well). You must ensure that such users do not load the post-loadable patches in their possession which are already included in the current image.
Here is a possible scheme which will work for applications which are distributed as runtime images. (This is not the only possible scheme or even the best for your situation. It illustrates how the tools and their features can be used to produce a scheme that works.)
*restart-init-function*, the following load-patches forms are evaluated:
(sys:load-patches :update-directory "sys:;update-myapp;" :product #\a)
(sys:load-patches);; to load any Allegro CL patches in
*restart-init-function*is changed to
(sys:load-patches :update-directory "sys:;update-myapp;" :product #\b)
Note that even if your customer ignores your instruction to delete the p[m]a[nnn].[vvv] files from myapp-update, those (no longer valid) patches will not be loaded because load-patches is looking for product b and those files have product a.
The discussion under the previous heading concerns distributing patches to users who cannot themselves build an original image with build-lisp-image. You, however, will build original images (and perhaps your customers are licensed to do so as well). How do you include patch files in the image when it is built? You put appropriate sys:load-patches forms in custom.cl and make sure all your patches are in the directories specified in the sys:load-patches forms. Allegro CL patches can be put in the update subdirectory (they will be included automatically by the image build process). See Use of custom.cl in building-images.htm.
Say you have sent a patch, p0a001.001 to your
users (the first 0 would actually be the value of
excl::*cl-patch-version-char*). The sys:defpatch form at the top of
the patch file is:
(sys:defpatch "0a001" 1 "Fixes whatever" :type :myapp)
A user complains that including the patch fixes the problem reported but seems to cause another problem. You check it out and find that the patch does introduce new problems. So you create a new version. You put it into a file and compile it to p0a001.002. The sys:defpatch form at the head of the file is:
(sys:defpatch "0a001" 2 "Fixes whatever" :type :myapp)
When the user gets the new patch, the patch loader will load it. But you should also provide a new, withdrawn version of the original patch file. Then the actual bad patch file no longer exists and cannot be accidentally loaded.
Bad (for whatever reason -- introduces a new bug or does not do what it was supposed to or whatever) patch files should be simply withdrawn. A speed-enhancement patch which actually slows things down is one example (your idea for a speedup failed and you do not have other ideas). We recommend replacing the defective patch file with a new file (same filename and version, so the bad file is overwritten) marked withdrawn. This shows the fact that the patch is withdrawn in the dribble-bug output. So, the sys:defpatch form in the replaced p0a001.001 would be (like above):
(sys:defpatch "0a001" 1 "Fixes nothing" :type :myapp :withdrawn t)
When the compiler processes this sys:defpatch form, it stops compiling the file. Therefore, you can leave the original patch source (for later reference) without worrying that the patch fasl file will be larger than necessary or contain bogus compiled code.
In the era of the World Wide Web, ftp, and users around the world, a typical way to distribute patches to users is having them download the patches from an ftp (or www) site directly into the appropriate directory without actual human contact between you and your users. If you use this model, you should tell your users to download every patch, you should use the version mechanisms we describe above, and you should tell your users to expect files to be overwritten.
You can also, of course, distribute patches on request, one at a time, with instructions (which usually include `delete all earlier versions of this patch!') The more patch distribution has a human-contact element, the less you have to worry about old version and bad patches not being deleted. The more the system is automated, with less handholding, the more being very careful about version numbers becomes necessary.
Patches are compiled lisp files, and such files can be loaded in a number of ways. There is no reason a post-loadable patch file cannot be loaded with load. Often that is useful for quick tests. However, Allegro CL provides a patch-loading function carefully integrated with the patch system described in this section. As far as possible we recommend that you load with sys:load-patches.
The function featurep returns true or
nil as the features called for in its argument are or
are not on
*features*. It is thus a functional analog of
the #+/#- reader macros. It is used by sys:load-patches to process the
feature argument in sys:defpatch forms.
Things to note
sys::abort-patch-loading. If that restart is found, it is invoked. If no such restart is found, an error is signaled. sys:load-patches sets up the restart but no such restart will (likely) be present when loading a patch file with load. Therefore, using load is best done with single or just a few patches but sys:load-patches should be used for any automated procedure or when many patches are involved. Note that loading patches marked withdrawn does not signal an error.
*features*while loading a patch since the patch file may add a feature to that list, but the addition will be lost when the binding is undone.
On Windows, you can turn your Common Lisp application into a Windows NT/2000/XP/Server 2003 service with the ntservice package. There is an example in the examples/ntservice/ directory.
If you have a Common Lisp application that you would like to start up automatically when the system starts, and shut down cleanly when the system is shutting down, then this package is for you.
Follow these steps and you'll be on the road to servicedom.
(eval-when (compile eval load) (require :ntservice))
(exit 0 :no-unwind t :quiet t)when the service is stopped (see exit). If you need things to happen before exit is called, use the stop keyword argument to ntservice:execute-service to pass in a function that can do cleanup.
If you want to remove your program from the list of services, you can use ntservice:delete-service to delete the service.
The LocalSystem account is very powerful! Be careful of what you allow your program to do. Also note that the LocalSystem account usually does not have access to network filesystems. This may lead to confusion if your service tries to access drive letters that are mapped to network drives, or if it tries to access remote filesystems via UNC names (\\host\\share\file).
You can use the Services control panel applet to change who the service runs as. Note that no account but LocalSystem will be able to interact with the desktop (i.e., your program's window will be invisible if you don't run as `LocalSystem').
See examples/ntservice/testapp.cl for an example skeleton for a service application.
To start and stop services programatically, you can use the ntservice:start-service and ntservice:stop-service functions.
The functions in the ntservice module are as follows. All are named by symbols in the ntservice package.
Arguments: service-name main &key init stop shutdown
service-name is a string naming the service. This name is the same name that is used when creating the service (with create-service). main should be a function (or a symbol naming a function) which constitutes the main loop of your program. This function will be called when the service starts running. No arguments are passed to this function. This function should never return (if it does, Windows will complain that the service terminated prematurely).
The keyword arguments init, stop, and shutdown are optional.
init specifies a function (or a symbol
naming a function) that should be executed before the main loop is
executed. Such a function might load in configuration settings or
verify the system environment. The init function
should be prepared to accept a single argument. This argument is the
list of "Start parameters" that have been specified for the service.
This list is usually empty but can be modified using the Services
control panel applet. If the init function
nil, the service will not be started
and an error will be logged and/or reported. Make sure
init returns non-
under normal circumstances.
stop specifies a function (or a symbol naming a function) that should be executed when the service is to be stopped. Such a function might do work that your application needs done before Lisp exits. This function should do its job fairly swiftly, otherwise Windows might complain that the service isn't stopping properly. No arguments are passed to this function.
shutdown is like stop and specifies a function (or a symbol naming a function) that should be executed when the service is to be stopped due to the computer being shut down.
Please remember that execute-service never returns to its
caller. It calls
(exit 0 :no-unwind t :quiet t) to
exit Lisp (see excl:exit).
Arguments: name displaystring cmdline &key (start :manual) (interact-with-desktop t) description username (password "")
name should be a string that identifies your service. The maximum string length is 256 characters. The service control manager database preserves the case of the characters, but service name comparisons are always case insensitive. Forward-slash (/) and back-slash (\) are invalid service name characters.
displaystring should be a string that contains the display name to be used by user interface programs to identify the service. This string has a maximum length of 256 characters. The name is case-preserved in the service control manager. Display name comparisons are always case-insensitive.
cmdline should be a string that contains the command line for executing your service program. The first word in the string should be the fully-qualified pathname to the executable.
start can either be
:manual, the service must be started and stopped
:auto, the service will start
automatically at boot time.
If interact-with-desktop is true (the default),
then the service will be allowed
to interact with the desktop. Note that on Windows Vista,
interaction with the desktop is limited, even with
interact-with-desktop is true. See
details. If interact-with-desktop is true, then
username (see below) must
nil, must be a string, which (typically)
explains the purpose of the service.
username specifies the name of the account
under which the service should run. If this parameter
nil or zero, the LocalSystem account will
password specifies the password for the account specified in username. Use a null string ("") if the account has no password.
If create-service is successful, it
t. If it is not successful, it
returns two values:
nil and the Windows error
code. You can use ntserver:winstrerror to convert the code
into a string.
(multiple-value-bind (success errcode) (ntservice:create-service "MyService" "My Common Lisp program service" "c:\\devel\\program\\program.exe /runfast /dontcrash") (if success (format t "all is well~%") (error "create-service failed: ~A" (ntservice:winstrerror errcode))))
Your service will be created with the following properties:
Manual start Run as LocalSystem account Allow program to interact with desktop
Arguments: name description
name must be the name of an existing
service. description must be a string or
existing description for the named service will be removed.
Otherwise, the service description for the name service will be set.
name is the name you gave the service in
your call to create-service. It seems to be
possible to request deletion of a running service. This disables the
service from further starts and marks it for deletion once it stops.
t if the removal was successful, otherwise it returns
nil, the Windows error code,
and a string with the name of the function that actually failed. You
can use ntserver:winstrerror to convert the code into a string.
Arguments: name &key (wait t)
name is the name of the service. If wait is true (the default), then this function will wait until it has confirmation that the service has started before returning.
Arguments: name &key (timeout 30)
name is the name of the service. timeout is the number of seconds to wait for the service to stop. Currently, this function does not automatically stop dependent services.
This tutorial will show you how to use the testapp example found in examples/ntservice/.
First, startup Allegro, and do this:
This will build the test application and put the result in
Now, start up a cmd.exe (Command Prompt) and do this:
This will install the test service. You can now start the test service by doing this:
net start MyService
The name MyService was set in testapp.cl and is just an example service name. You should see an Allegro CL console window with contents something like this:
You can either close the application (with the close button on the window) or you can shut down the service by doing this:
net stop MyService
Both methods for stopping the service will work.
Copyright (c) 1998-2012, Franz Inc. Oakland, CA., USA. All rights reserved.
Documentation for Allegro CL version 9.0. This page was not revised from the 8.2 page.
|Allegro CL version 9.0|
Unrevised from 8.2 to 9.0.