Method and system for automated provision of build images

A method for automated provision of build images is disclosed. The method includes identifying the network location of build scripts that provide information regarding the installation of installation files and copying the build scripts from the location on the network to a memory, e.g., a disk drive of a target computer system. In addition, the method includes copying installation files that correspond to the build scripts to the drive of the target machine. The installation files are subsequently installed on the target machine to create the build image.

FIELD OF THE INVENTION

The present invention relates generally to the automated installation of software programs. In particular, embodiments of the present invention relate to a method and system for automated construction of build images.

BACKGROUND OF THE INVENTION

A software image is a preinstalled computer system software package. Consumers receive commercially available versions of such packages routinely as an included feature of the computer systems that they purchase. Such software images provide the owners of such computer systems with the immediate capacity to make effective use of their computers. As a result, these systems are highly valued by consumers. Consequently, the development of ever more marketable versions of such software images is pursued by computer system manufacturers.

Conventional methods of creating software images involve the manual Installation of each software component that is included in the images. Such manual methods of creating software images are tedious and time consuming as each piece of software is manually installed on a single computer that contains the image. In addition, the images that are created may not be consistent. This is readily apparent when it is considered that different engineers are likely to install the same software program differently or that the same engineer may install the same software program differently on different systems (or on different occasions for that matter). Moreover, as with any manual process the manual installation of software is prone to errors.

A “build” is a version of a software image. A software image may undergo many iterations or “builds” during the course of its development. It should be appreciated that the different versions that are created need to be tracked so that they do not become confused. Difficulties tracking the software image versions may be compounded by the large number of programs and computer platforms that may be involved in a build. The large number of software types, build versions and computer system platforms that are involved can present challenges that are not easily managed.

The management challenges are especially apparent when considering the manual procedures used to construct the builds. It would not be uncommon for a single computer vendor to have to support some 50 or more different builds considering the different program versions involved and the different computer platforms involved. It should be appreciated that these complications present a significant challenge to the manual performance of the tasks involved in managing successive build images.

SUMMARY OF THE INVENTION

Accordingly, a need exists for a method and system for automated provision of build images. The present invention provides a method and system that accomplishes this need.

Embodiments include a system that includes a database, a server, a target machine and an automated build utility or ABU. In the database, information regarding programs, their version, identity and source installation code is provided. Also provided in the database is a script. The script informs the ABU of the programs that are to be installed on the target machine. The server contains the programs. Generally, the ABU reads a script, associated with a build, and follows the instructions in the script to install the identified programs on the target machine automatically. The ABU also contains a number of graphical user interfaces that aid an engineer in the process of automatically constructing the build. Different builds can be constructed by merely changing the contents of the script file.

According to one embodiment of the present invention a method for automated provision of build images is disclosed. The method includes identifying the network location of build scripts that provide information regarding the installation of installation files, and copying the build scripts from the location on the network to the hard drive of a target machine. In addition, the method includes copying installation files from a server where the files correspond to the build scripts. The files are copied to the hard drive of the target machine. In one implementation a magnetic hard drive is used but an optical drive could also be used. The installation files are subsequently installed on the target machine to create the build image.

According to one embodiment, an automated build utility (ABU) is disclosed. The ABU includes a processor, a memory device that includes computer executable instructions stored therein for performing a method for providing an automated build image including identifying the network location of build scripts that provide information regarding the installation of installation files and copying the build scripts from the location on the network to the drive of a target machine. In addition, the method includes copying installation files that correspond to said build scripts to the drive of said target machine. The installation files are subsequently installed on the target machine to create the build image.

In still another embodiment, a network is disclosed. The network includes a server, a database, a target machine and an automated build utility (ABU). According to this embodiment the ABU copies build scripts obtained from the database, and installation files obtained from the server; to the drive of the target machine, and automatically creates a build image.

These and other advantages of the present invention will no doubt become obvious to those of ordinary skill in the art after having read the following detailed description of the preferred embodiments which are illustrated in the drawing figures.

DETAILED DESCRIPTION OF THE INVENTION

NOTATION AND NOMENCLATURE

Some portions of the detailed descriptions which follow are presented in logic blocks or other symbolic representations of operations on data bits within a computer system or electronic computing device. These descriptions and representations are the means used by those skilled in the data processing arts to most effectively convey the substance of their work to others skilled in the art. A logic block, process, etc., is herein, and generally, conceived to be a self-consistent sequence of steps or instructions leading to a desired result. The steps are those requiring physical manipulations of physical quantities. Usually, though not necessarily, these physical manipulations take the form of electrical or magnetic signals capable of being stored, transferred, combined, compared, and otherwise manipulated in a computer system or similar electronic computing device.

It should be borne in mind, however, that all of these terms are to be interpreted as referencing physical manipulations and quantities and are merely convenient labels and are to be interpreted further in view of terms commonly used in the art. Unless specifically stated otherwise as apparent from the following discussions, it is understood that throughout discussions of the present invention, discussions utilizing terms such as “identifying” or “copying” or the like, refer to the action and processes of an electronic computing device that manipulates and transforms data.

Exemplary Network in Accordance with Embodiments of the Invention

FIG. 1Ashows a block diagram of an automated build utility (ABU) network100according to one embodiment of the present invention. The ABU network encompasses an automated software installation infrastructure that features a software installation methodology that may be applied repetitively in the installation of new program versions or “builds”.FIG. 1Ashows ABU101, database103, target machine (e.g., personal computer)105and network server107.

Automated build utility unit (ABU)101facilitates the rapid creation of builds by automating the installation and configuration tasks that are performed in the creation of a build. A build is a digital image representing one or more installed programs on the target machine. The build can exist on an optical or magnetic hard drive or can also reside in any computer readable medium such as RAM or ROM, etc. According to one embodiment, the ABU101collects program components from the network server107and configures them according to specifications that are obtained from a database (e.g.,103). Unless modified, the same process that is employed in the creating of one program build is employed in the building of subsequent program builds. A consonant build process that is executed each time a build is created is thereby assured. Once the build is created for a particular target platform, it can be easily copied onto each computer product, e.g., for sale.

Database103contains build scripts that direct software installation. Each script can control the generation of a respective build. The build scripts direct the selection and configuration of program components that are to be employed in the creation of the build. Information provided by the build scripts may include but is not limited to software identification information, server path, program specific installation instructions, special installation instructions for individual programs, special installation instructions for the build being created, registry information, version number, etc. A separate script, and separate build can be provided for each computer platform on which software is to be installed. Also, separate scripts can be used for separate software versions of the installed software.

The software image (e.g., “build image”) to be installed may be described in a bill of materials (BOM).FIG. 1Bshows a section of an exemplary BOM that is configured according to one embodiment of the invention. The script related to the BOM will contain identifications of the software outlined in the BOM and an installation order thereof. The fields of the BOM may include but are not limited to software title131, SITD133, version135, champion137(engineer) and build information139(seeFIG. 1B). It should be appreciated that the build information139includes installation details related to the version135of the software title131that is listed in the BOM120. The engineer137may use this information when creating the script for the build image. This information represents a type of data that may be stored in database103.

Network server107stores the code for the software programs that may be installed by the ABU. The network server also stores the operating system (e.g., windows etc.) and program drivers that are necessary to operate software program. These components together form a software image.

The target machine (e.g., VAIO PC etc.)105is the target personal computer the software is to be installed on, although any computer system may be used. The ABU101installs software that resides in the database103onto this machine. Build scripts that are obtained from the database103provide the ABU with a blueprint to the installation of the latest versions of the software components of a software build image.

FIG. 2is a functional block diagram200of an exemplary image build system according to one embodiment of the present invention.FIG. 2shows ABU101, database103, script generator201, build scripts203, code source107, and build image207.

Referring toFIG. 2, ABU101automatically obtains software code from code source107(e.g., server107etc.). The ABU also automatically obtains build scripts203from database103that correspond to the software obtained from the code source. The build scripts203provide a blueprint that directs the configuration and installation by the ABU101of the software images207that comprise a build. The latest revision of the software is installed on a target machine (e.g., PC105) according to the ABU101.

Graphical User Interface

FIG. 3Ashows a graphical user interface (GUI)300with a layout configured according to one embodiment of the present invention. The GUI300facilitates user control of the ABU's automated build creating operations by accommodating user inputs. In addition the GUI300displays useful information about these operations and facilitates their customization. It should be appreciated that the GUI300may provide windows that display a listing of the installation files (e.g., operating systems, software, drivers etc.) that have been identified for use in a particular build along with an indication of the statuses, of the identified installation files. Moreover, the GUI300may include a series of graphically rendered button functions whose activations trigger the execution of the ABU's aforementioned automated software installation operations.FIG. 3Ashows tool bar303, path to network build script files folder display305, status area toolbar301, log statistics display309, image type select310, user options window311, copy build scripts button function313, copy installation files button function315, execute button function317, and verify button function319.

Installation File Selection/Status

Installation file status window301A lists and provides an indication of the status of items (e.g., installation files) that have been identified for copying from the network (e.g., network server107). The items listed are the programs that may be installed in the creation of an image build and are defined by the script shown as305. Status area toolbar301facilitates the selection of the items that are listed in the installation file status window301A. As the ABU installs the programs identified in301A, their respective status is updated. Status indicates if an installation was completed or if an error was encountered. It should be appreciated that some or all of the items listed in the window may be selected.

According to one embodiment, a custom copy installation function may be provided. By employing this function user specified files selected from among the items listed in the installation file status window301A may be copied to the local hard disk. According to this embodiment, installation files may in this manner be copied to hard disk before their installation may be executed through the operation of the ABU.

FIG. 3Bshows a GUI status list area window301A, such as is shown inFIG. 3A, which displays a representation of its contents at a point during a build process performed in accordance with one embodiment of the present invention. As is shown inFIG. 3Bthe status list area window may display a listing of the installation files and an indication of their existing status in the file installation process. Referring toFIG. 3B, the designations “C”, “V”, and “” indicate respectively that installation files have been copied but not executed, not verified and verified.FIG. 3Cshows a window that tracks the aforementioned copying process by presenting a graphical representation of the overall progress of the process.

FIG. 3Dis a diagram of the status area toolbar301according to one embodiment of the present invention.FIG. 3Dshows “X” button function301B, “Save Xs” button function301C, “Load Xs” button function301D, “Mark Items” button function301E and “Toggle Items” button function301F. According to one embodiment, the selection of the “X” button function301B toggles all the check boxes “on” or “off”. Selecting the “Save Xs” button function301C saves all checkmarks to memory where they may be recalled by a selection of the “Load Xs” button function301D. It should be appreciated that these checkmarks may be saved until the “Load Xs” button function301D is selected or until the program is exited. According to one embodiment, this may be the only program operation that will clear the memory of the checkmarks saved using this feature.

According to one embodiment, while the “Load Xs” button function301D recalls the checkmarks that have been saved into memory by the “Save Xs”301C feature, selecting the “Mark Items” button function301E identifies each selected item with a checkmark. It should be appreciated that multiple items can be selected in one of two ways: (1) by left clicking (e.g., as with a mouse) an item and then while holding the shift key, left clicking another item; or (2) by holding down the Ctrl key (e.g., of a keyboard) while left clicking each item. The “Toggle Items” button function301F toggles the checkmarks of all items selected “on” or “off” depending on the checkmarks previous state (“on” or “off”).

According to one embodiment, the installation file status window301A can display up to twenty items (e.g., installation files) at a time for instance. However, more than twenty items can be accommodated by a vertical slider bar that automatically becomes available. According to one embodiment, each item may possess an associated check box. The check boxes allow a system user to distinguish items that are of interest. It should be appreciated that ABU operations such as the copying, installation execution and verification of installation files rely on the checkmarks to identify the particular installation files that are of interest when an installation operation (e.g., copying, execution, verification etc.) is being customized. As a result, items selected for copying, execution and verification may be processed as usual unless distinguished by a check mark.

According to one embodiment, each item listed in the installation file status window301A may be denoted with an associated number. When the status list displays only “base plus” items (e.g., a default listing of items), the numbers that denote the items relate directly to numbers taken from the build scripts that are associated with the items. This also applies when the list only displays “full image” items (e.g., a complete listing of items that when installed constitute an image). It should be appreciated, however, that when both “base plus” and “full image” items are displayed in the list area the “base plus” items may be numbered prior to the numbering of the full image items, according to one embodiment of the present invention.

FIG. 3Eillustrates the operation of the “Mark Items”301E feature according to one embodiment of the present invention. This operation may be controlled by manipulating the “Mark Items” button function301E shown inFIG. 3D. InFIG. 3Eall of the items that have been selected to undergo an installation operation are distinguished by means of a checkmark (see discussion above). As is shown, icons such as “V”, “C”, “” etc. may be used to represent the various program status stages as was discussed above.

FIG. 3Fillustrates the operation of the “Mark Items”301E ABU feature according to one embodiment of the present invention. This operation may be controlled through the manipulation of the “Mark Items” button function301E shown inFIG. 3D. InFIG. 3Fas inFIG. 3E, all of the items that are selected to undergo an installation operation are distinguished by means of a checkmark. However, inFIG. 3Fonly some of the installation files listed are selected for installation. This indicates that the build image that will be produced from an installation of the selected files may not be a full image.FIG. 3Gillustrates the operation of the “Toggle Items”301F ABU feature according to one embodiment of the present invention. This operation may be controlled through the manipulation of the “Toggle Items” button function301F shown inFIG. 3D. As is shown inFIG. 3G, through the actual manipulation of the “Toggle Items” button function301F all of the checkmarks that previously distinguished the selected items shown inFIG. 3Fhave been removed.

Copy Build Scripts to D Button Function

Copy build scripts to D button function313(seeFIG. 3A) is a graphically rendered button function (e.g., icon) whose activation triggers the copying of build scripts that are provided by the database. Upon its activation the build scripts may be copied to the installation drive of a target machine e.g., the “D” drive in this example however any drive could be used. The build scripts provide a blueprint from which a build may be created by the ABU (e.g.,101).

Copy Installation Files Button Function

Copy installation files button function315(seeFIG. 3A) is a graphically rendered button function (e.g., icon) whose selection triggers the copying of installation files. The installation files that are copied are taken from installation files that are listed in the installation file status window. The installation files are selected based on the image build that is being created. As previously discussed the selected files may represent “base plus” or “full image” files or both.

Execute Installation Button Function

Execute installation button function317(FIG. 3A) is a graphically rendered button (e.g., icon) whose selection triggers the installation of the installation files that have been copied. According to one embodiment, the installation files are installed onto a target machine (e.g., PC etc.) that is designated by the ABU. In one embodiment, the installation of the installation files onto the target machine completes the build creating process if verification of the installed installation files (e.g., software, drivers etc.) is not otherwise warranted.

FIG. 3Hshows a display300H that presents data related to the execution of file installation processes described herein according to one embodiment of the present invention. As is shown inFIG. 3H, information displayed includes but is not limited to the application name320, version321, method322, command323, version path324, version325, verified,326and installment instructions327(seeFIG. 3Hfor data displayed in one embodiment). According to one embodiment, the display facilitates the copying of specific script information to an internal clipboard for later addition to a cleanup script (seeFIG. 6A–6Cand accompanying discussion of cleanup scripts). It should be appreciated that script having associated manual instructions which cannot be executed by the ABU101can first be copied to an internal clipboard (seeFIG. 3H) and be thereafter accessible from the internal clipboard through the cleanup macro option (see discussion ofFIG. 3Nbelow) from the options menu303D. It should be noted that the folder icon341shown to the left of the “Add to Clipboard” button function338(seeFIG. 3H) opens the source folder used by the ABU (e.g.,101) to install applications. Other functions accommodated by display300H are shown inFIG. 3H(e.g., stop336, pause335, close this window337, reboot339, and shut down340etc.) according to one embodiment of the present invention.

FIG. 3Ishows the execution options window320according to one, embodiment of the present invention. The execution options window320may be made available by checking the “Use Execution Options” box (seeFIG. 3I) located in the options window (located on toolbar303) and the options are relevant to a program that is highlighted in window301A. That is, during the execution of the selected programs installation, one or more execution options can be performed according to this GUI. As the name suggests, execution options only apply to program execution after the execute button function317has been selected. The execution options do not affect any other action. As is shown inFIG. 3I, the execution options available through this menu (e.g.,320) include but are not limited to “Reboot”328, “Pause”329and “Pause for” (e.g., pause for an amount of time)330. This function allows reboots, pauses until continue, and timed pauses to be scheduled into the actual build execution as associated with the highlighted program. Other functions available through this menu include but are not limited to “Save Options”331, “Load Saved options332”, “Add”333and “Remove”334(seeFIG. 3Istructure320).

It should be appreciated that in one embodiment adding and removing execution options is done in memory and may not be saved to disk therefore none of the options will exist when the program exits. However, by selecting the “Save Options” button (seeFIG. 3I) function331execution options may be saved to disk. Moreover, they may be uploaded from the disk when the “Load Saved Options” button function332(seeFIG. 3I) is selected.

According to one embodiment of the present invention, scheduled pauses may be added to the build script. It should be appreciated that the user may set the pause time. According to one embodiment, this item may then be added to an integrated status area GUI (seeFIG. 3G). Although the addition of pauses may be made available as a cleanup operation (see discussion accompanyingFIG. 6) these pauses, according to exemplary embodiments, may be limited to before or after executions.

It should be appreciated that an execution option (e.g., pause etc.) may be added by first selecting an item in the installation file status window301A and by next selecting the “Add” button function333(seeFIG. 3I). The execution option (e.g., pause etc.) will thereafter be placed ahead of the selected item in the installation file status window (seeFIG. 3Gsolid square). According to one embodiment, execution options may be added one at a time. An item may be deleted by first selecting an item in the installation file window and next selecting the “Remove” button function334(seeFIG. 3I). Other execution options available include time pauses scheduled for execution during builds and reboots scheduled for execution during builds (seeFIG. 3I).

Verify Installation Button Function

Verify installation button function319(FIG. 3A) is a graphical button function whose activation triggers the ABU101verification of a program that has been installed. Version verification can be an important operation in the tracking of software that has already been installed. According to one embodiment, the ABU101may provide this function. It should be appreciated that both successful and failed version verification events may be logged. However, according to one embodiment, extensive pattern matching and error checking may be provided by the ABU as a means of ensuring successful version verification. It should be appreciated that the type of version information that may be employed to effect version verification may encompass a wide range of data. This data may include but is not limited to executable, registry key, registry value, date, and text.

FIG. 3Jshows a GUI such as is shown inFIG. 3Aincluding installation file status window301A which displays a listing of the identified installation files and an indication of their existing status in the file installation process. It should be appreciated that a checkmark indicates that an item has been verified while a “V” indicates that the item could not be verified. Moreover, the items that are distinguished by a black “C” have been copied to the local disk but have not been executed while items not distinguished by any status icon at all have not been copied to the local disk.FIG. 3Kshows a GUI for a “Check Version” tool 300K that facilitates custom version checking according to one embodiment of the present invention. The GUI may include fields for network path342, version ID343, Version344and Verified345. Button functions may include “Verify”347, “Browse”346and “Clear All”348.

Other GUI Features

Log statistics display window309(seeFIG. 3A) displays statistics that are compiled by operation of a program log. The underlying log program keeps track of the total number of programs, the total number of programs verified and the percentage of the total number of programs that are verified. In addition, all program executions, registry changes, and version verification results are logged. During custom executions only those items that were actually executed are logged. The logging operations themselves are split between two main log files: (1) the build log file; and the (2) program log file.

The build log file is a master log file containing all of the items that are logged while the program log file may contain as many entries as there are sections in the build script(s). It should be appreciated that the program log file is a persistent storage version of the installation file status window301A. According to one embodiment, programs that have previously failed version verification because they have not been executed may have their status verified in the program log if they are late executed and verified. It should be appreciated that unlike the build log, in the program log, entries may only be entered for each section of build script.

The path to network build script files folder display305(seeFIG. 3A) displays a description of the path to the network address where the file folder is located that contains the build scripts for an installation file identified for installation. The information shown in the display describes the specific location of the file folder that contains the build scripts.

Toolbar303(seeFIG. 3A) includes file303A, edit303B, build303C, options303D, tools303E, and help menus303F.FIG. 3Lis a graphical illustration of a file menu303A window configured according to one embodiment of the present invention. One embodiment of the present invention includes a file menu303A that features a file/open select function. This allows commonly referred to scripts to be opened directly from the ABU. Other exemplary functions are shown in the menu depicted inFIG. 3L. However those shown are only exemplary and the actual menu may include but is not limited to the functions shown.FIG. 3Mis a graphical illustration of one embodiment of an edit menu window according to one embodiment of the present invention. This menu may include but is not limited to cut, copy, and paste editing functions.

FIG. 3Nis a graphical illustration of an options menu303D window configured according to one embodiment of the present invention. One embodiment of the present invention includes but is not limited to an options menu303D that lists such system functions as “logging” (e.g., simple and advanced), “log registry changes”, “alert on version conflict”, “use execution options”, “do before cleanups”, “do after cleanups”, “increase pause time”, “decrease pause time”, “do before cleanups now”, “do after cleanups now”, “check all versions now” and “save settings on exit” (see options menu303D listings inFIG. 3N).

FIG. 3Oshows a graphical illustration of a tools menu303E window configured according to one embodiment of the present invention. The tools menu303E allows access to such system functions as “Cleanup Macro”, “Check Version” and “Log Statistics”. “Cleanup Macro” provides an interface (not shown) that accommodates the entry of information that directs the creating and editing of cleanups. “Check Version” is a stand alone program used to verify program installation. Because of the stand alone nature of the program, actions performed through “Check Version” program do not affect ABU processes. It should be appreciated that the same verification results may be displayed by both the ABU and the “Check Version” program as they both use the same underlying version verification code. Log statistics provide access to a display that presents verification statistics taken from a log file.

FIG. 3Pis a graphical illustration of a help menu303F window configured according to one embodiment of the present invention. Functions that may be included on the help menu303F include but are not limited to help functions such as “walk me through a build” and “about”.

Image type select310facilitates a selection of a desired image type to be installed. Image types that may be selected include base images and full images. According to on embodiment, a base image is a subset of the full image. According to such embodiments the base image may consist of a program package that includes an operating system and its drivers. In other embodiments other base image packages may be employed. A full image is a complete image that is derived from the installation of all of the installation files identified by the ABU (e.g.,101) as corresponding to it.

User options section311(seeFIG. 3) facilitates the selection of such user options as are described herein. These optional settings include but are not limited to version conflict alert311A, logging type311B (e.g., simple or advanced), registry tracking311C (e.g., log registry changes), cleanups311D (e.g., before and after) and pauses311E.

FIG. 4shows a graphical user interface (GUI)400that facilitates the browsing of network folders for OEM Pre-Install Kit (OPK) files according to one embodiment of the present invention. This GUI may be employed to browse, network folders for OEM Pre-Install Kit (OPK) files. It should be appreciated that base OEM Pre-install Kit (OPK) files may be copied from the network to a specific project location (e.g., a specific PC etc.) on the network. According to one embodiment, ABU configuration files such as for example, “winbom.ini” and “unattend.txt” may be altered to reflect settings (which reflect the project version) in the current project. Project specific OPK drivers, quick fix engineering (QFE) releases and Most Frequently Used (MFU), links can also be added to the configuration set. All these tasks are outlined in an ABU script file. According to one embodiment the file may be designated “opkscript.ini” and is generated by a script generator (e.g., ScriptGen etc.) located in the database (e.g., VSMS etc.). In other embodiments other file designations may be employed. The OPK creation feature may contain no main application GUI window, but may provide sub windows that solicit needed input and pop-ups for information output.

FIG. 5A–5Cshows the windows and dialog boxes presented to a system user during the OPK creation process according to one embodiment of the present invention.FIG. 5Ais a window500A that tracks the file copying process according to one embodiment of the present invention.FIG. 5Bis a window500B that displays a request that a user insert a removable disk in order to store files to be copied according to one embodiment of the present invention.FIG. 5Cis a window500C that indicates that the file copying process is complete according to one embodiment of the present invention.

Cleanup Generation and Execution

FIG. 6Ashows cleanup GUI interface600A according to one embodiment of the present invention. The cleanup generation and execution feature facilitates the creating, editing and executing of cleanup scripts at or near the completion of the installation process, in one embodiment. It should be appreciated that cleanup scripts are used to make changes to the image build that were not already present or completed by program installation execution operations. It provides a way to automate and keep track of manual steps and to make other necessary changes to the image build. These changes may later be included in the build scripts. There are two basic types of cleanups, cleanups that are set to occur before program installation execution and cleanups that are set to occur after program installation execution. According to one embodiment, each of these cleanup types may occur each time an application is run within ABU101. It should be appreciated that cleanups may be run in a custom fashion irrespective of whether an application is executed.

According to one embodiment of the present invention, in order for the ABU to recognize a cleanup file it should be saved in an “INI” format with either the “.ini” or “.cln” file name extension. It should be appreciated that before cleanups may be saved to an ABU\before directory while after cleanups may be saved to an ABU\after directory. Custom cleanups not intended to be run either before or after program execution can be saved to any location.

FIG. 6Bshows a before cleanup list window600B that is available from the main GUI according to one embodiment of the present invention. Available cleanup files are listed in the options menu303D window of the main GUI. Any “.cln” or “.ini” files that are located in the before and after cleanup directories may be listed in the B619and A621cleanups lists respectively (seeFIG. 6B). Each item from the lists may be selected and viewed with view details. Selecting a file opens the file and displays its contents within a cleanup Ini generator. In addition, the execution of selected cleanup files may be effected by selecting the “Do Cleanups” button function622shown inFIG. 6B.

FIG. 6Cshows a custom cleanup file management GUI600C that displays files located in a custom directory according to one embodiment of the present invention. It should be appreciated that cleanup files may be saved to such a custom directory and may be listed in the “Other Cleanups” list625. This may be accomplished by utilizing the “Browse” button function627to designate the custom directory selected to accommodate the cleanup files. As above the execution of selected cleanup files may be effected by selecting the “Do Cleanups” button function629shown inFIG. 6C. As with before and after cleanups discussed above, any cleanup files located within the designated directory may be displayed within a cleanup Ini generator.

Exemplary Operations in Accordance with Embodiments of the Present Invention

FIG. 7shows a flowchart700of the steps performed in processes of the present invention which, in one embodiment, are carried out by processors and electrical components under the control of computer readable and computer executable instructions. The computer readable and computer executable instructions reside, for example, in data storage such as memory units804and806(seeFIG. 8). However, the computer readable and computer executable instructions may reside in other types of computer readable medium. Although specific steps are disclosed in the flowcharts, such steps are exemplary. That is, the present invention is well suited to performing various other steps or variations of the steps recited in the flowcharts. Within the present embodiment, it should be appreciated that the steps of the flowcharts may be performed by software, by hardware or by a combination of both.

FIG. 7shows a flowchart700of the steps performed in the automated creation of image builds according to one embodiment of the present invention.

At step701, the network location of the build scripts is specified. According to one embodiment, the database103stores build scripts that are generated by script generator that resides therein. These build scripts may be accessed by the ABU101for use in the build creation process.

At step703, the build scripts residing at the location specified in step701are copied to a targeted machine. In one embodiment the memory is a disk drive. This operation may be facilitated by using the copy build scripts to D button function313on ABU GUI300. Copy build scripts to D button function313(seeFIG. 3A) is a graphically rendered button function (e.g., icon) whose activation triggers the copying of build scripts that are provided by the database. The build scripts provide a blueprint from which a build may be created by the ABU. As described above, the script identifies a set of programs to be installed on the target device and the ordering of such installation and identifies any auxiliary or support programs that may be necessary to perform a software installation.

At step705, installation files or program source corresponding to the build scripts copied to the drive of the targeted machine in step703are copied from the database to the drive of the targeted machine. This operation may be facilitated by using the copy installation files button function315. The copy installation files button function315(seeFIG. 3A) is a graphically rendered button function (e.g., icon) whose selection triggers the copying of installation files. The installation files that are copied are selected from the group of installation files that are listed in the installation file status window. The installation files are selected based on the image build that is being created. As previously discussed the selected files may represent “base plus” or “full image” items or both.

At step707, the installation files are automatically installed onto the target machine (e.g., PC etc.) by following the instructions in the identified scripts as applied to the loaded software. The installation may be facilitated through the use of the execute installation button function317. Execute installation button function317is a graphically rendered button (e.g., icon) whose selection triggers the installation of the installation files that have been copied. As the files are individually installed in sequence, window301A is updated to reflect status information, etc.

At step709, the version of the installed software is verified. Each program may be verified individually. This may be facilitated through the use of the version verification button function319. The version verification button function319is a graphically rendered button function whose activation triggers the ABU (e.g.,101) verification of a program that has been installed. It should be appreciated that version verification can be an important operation in the tracking of software that has already been installed.

At step711, cleanup operations are performed. The generation and execution of cleanup scripts may be facilitated through the use of cleanup GUI600A. The cleanup generation and execution feature facilitates the creating, editing and executing of cleanup scripts. It should be appreciated that cleanup scripts may be used to make changes to the image build that were not already present or completed by program installation execution operations. At the completion of process700, an image build is generated that corresponds to the Installation of the software identified in the script.

Exemplary Hardware in Accordance with Embodiments of the Present Invention

FIG. 8is a block diagram of an exemplary computer system800in accordance with embodiments of the present invention. It should be appreciated that system800is not strictly limited to be a computer system. As such, system800may be well suited to be any type of computing device (e.g., server computer, embedded computing device, etc.). Within the following discussions herein, certain processes and steps are discussed that are realized, in some embodiments, as a series of instructions (e.g., software program) that reside within computer readable memory units of computer system800and executed by a processor(s) of system800. When executed, the instructions cause computer800to perform specific actions and exhibit specific behavior which is described in detail below. According to one embodiment, the instructions may include code that when executed perform the steps in the flowchart discussed herein with reference toFIG. 7. It should be appreciated that according to one embodiment these instructions may be resident in the ABU101. In other embodiments these instructions may be resident in other network devices.

Computer system800ofFIG. 8comprises an address/data bus814for communicating information, one or more central processors802coupled with bus814for processing information and instructions. Central processor unit802may be a microprocessor or any other type of processor. The computer800also includes data storage features such as a computer usable volatile memory unit804(e.g., random access memory, static RAM, dynamic RAM, etc.) coupled with bus814for storing information and instructions for central processor(s)802, a computer usable non-volatile memory unit806(e.g., read only memory, programmable ROM, flash memory, EPROM, EEPROM, etc.) coupled with bus814for storing static information and instructions for processor(s)802. System800also includes one or more signal generating and receiving devices808coupled with bus814for enabling system800to interface with other electronic devices. The communication interface(s)808of the present embodiment may include wired and/or wireless communication technology. For example, in some embodiments, the communication interface808is a serial communication port, but could also alternatively be any of a number of well known communication standards and protocols, e.g., Universal Serial Bus (USB), Ethernet, FireWire (IEEE 1394), parallel, small computer system interface (SCSI), infrared (IR) communication, Bluetooth wireless communication, broadband, and the like.

The system800may also include a computer usable mass data storage device812such as a magnetic or optical disk and disk drive (e.g., hard drive or floppy diskette) coupled with bus814for storing information and instructions. An optional display device810may be coupled to bus814of system800for displaying video and/or graphics. It should be appreciated that optional display device810may be a cathode ray tube (CRT), flat panel liquid crystal display (LCD), field emission display (FED), plasma display, or any other display device suitable for displaying video and/or graphic images and alphanumeric characters recognizable to a user.

As noted above with reference to exemplary embodiments thereof, a method and system for automated provision of build images is disclosed. The method includes identifying the network location of build scripts that provide information regarding the installation of installation files and copying the build scripts from the location on the network to a memory, e.g., a disk drive of a target machine. In addition, the method includes copying installation files that correspond to the build scripts to the D drive of the target machine. The installation files are subsequently installed on the target machine to create the build image.