An improved method for program building uses predefined source files and predefined build scripts comprising a sequence of build commands; wherein each build command comprises an origin command line interpretable by an operating system and addressed to at least one compiling tool.
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1. A method for program building using predefined source files and predefined build scripts comprising a sequence of build commands;
wherein each build command comprises an origin command line (20) interpretable by an operating system (7) and addressed to at least one compiling tool (10);
wherein each command line (20) comprises at least one of the following:
a source file name (22), a destination file name (24), a program name (25), an indication of at least one action (26) to be performed by said at least one addressed compiling tool (10), and an option (28) related to a corresponding action (26) to be performed;
wherein each origin command line (20) is parsed to identify components (22, 24, 25, 26, 28) of said corresponding build command;
wherein each identified component (22, 24, 25, 26, 28) is evaluated against rule sets (32) containing conditions and instructions to change said origin command line (20),
wherein matching rule sets are processed to generate at least one resultant command line interpretable by said operating system (7),
wherein processing of said at least one resultant command line by said operating system (7) produces at least one of the following:
an intermediate output file recursively processed by at least one additional command line, and a final output file interpretable by a target hardware platform (50), and wherein said rule sets (32) comprise predicate conditions (38) and command line component modification instructions (34) and runtime script declarations (36), wherein a cartesian product is formed based on said input dimensions and said rule sets (32) stored in a knowledge database (5), wherein for each command line component (22, 24, 25, 26, 28) satisfying said predicate conditions (38) of a rule set (32), corresponding command line component modifications (34) are applied and corresponding scripts (40) are invoked at defined points in program flow.
8. A system for program building comprising:
a memory; and
a processor, wherein the processor in combination with the memory is configured to provide:
A resource pool (9) with predefined source files and predefined build scripts comprising a sequence of build commands; a unified build frontend (12) and at least one compiling tool (10),
wherein each build command comprises an origin command line (20) interpretable by an operating system (7) and addressed to at least one compiling tool (10);
wherein said unified build frontend performs (12) the steps of:
Receiving said predefined source files and said sequence of build commands from said operating system (7),
wherein each command line (20) comprises at least one of the following:
A source file name (22), a destination file name (24), a program name (25), an indication of at least one action (26) to be performed by said at least one addressed compiling tool (10), and an option (28) related to a corresponding action (26) to be performed;
loading a control file (30) stored in a knowledge database (5) containing rule sets (32) with conditions (38) and instructions in order to modify said origin command line (20);
parsing each origin command line (20) to identify components (22, 24, 25, 26, 28) of said corresponding build command; wherein each identified component (22, 24, 25, 26, 28) is evaluated against said rule sets (32),
processing matching rule sets to generate at least one resultant command line interpretable by said operating system (7), and
outputting said resultant command line to said operating system (7),
wherein said operating system (7) processes said at least one resultant command line and produces at least one of the following:
An intermediate output file recursively processed by at least one additional command line, and a final output file interpretable by a target hardware platform (50), wherein said rule sets (32) comprise predicate conditions (38) and command line component modification instructions (34) and runtime script declarations (36), wherein said unified build frontend (12) forms a cartesian product based on said input dimensions and said rule sets (32) stored in said knowledge database (5), and
wherein said unified build frontend (12) applies corresponding command line component modifications (34) for each command line component (22, 24, 25, 26, 28) satisfying said predicate conditions (38) of a rule set (32) and invokes corresponding scripts (40) at defined points in program flow.
2. The Method according to
3. The Method according to
A pre-compile script and a post-compile script.
4. The Method according to
6. A data processing program for execution in a data processing system comprising: a processor, and a memory in communications with said processor, wherein the memory contains software code portions for performing a method for program building according to
7. A computer program product stored on a non-transitory computer-usable medium, comprising non-transitory computer-readable program means for causing a computer to perform a method for program building according to
9. The system according to
10. The system according to
A pre-compile script and a post-compile script.
11. The system according to
Replacing, deleting and appending components (22, 24, 25, 26, 28) of a corresponding origin command line (20).
12. The system according to
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1. Field of the Invention
The present invention relates in general to the field of program building for generating computer code interpretable by a target hardware platform, and in particular to a method for program building, and a system for program building using predefined source files and predefined build scripts. Still more particularly, the present invention relates to a data processing program and a computer program product for program building.
2. Description of the Related Art
Computer programs that run native on central processing units without runtime software interpretation are produced when human authored source code is translated into machine code by another program called a compiler. A compiler is typically a generic program that converts valid human readable source code to machine instructions. Commercial software foundries that produce large software programs typically use automated build processes to translate many thousands of source code files into machine code.
Performance of a software solution running on a particular hardware platform is dependent on multiple factors. One factor is the quality of code generated by the compiler that is used to build the software. A state of the art compiler can be instructed to generate highly optimized code; but this requires influencing the options that are passed to the compiler.
The SAP kernel, for example, is a composition of many thousands of c-modules compiled and bound together by instructions residing in over 170 make-files. These make-files are written by SAP and are, for the most part, platform agnostic.
The basic issue is; how to build an optimized kernel given the following conflicting factors, that the used compiler requires specific options to build optimized code, and the make-files—the instructions used to build the kernel—are platform agnostic; and therefore cannot be modified to suit a particular needs of a vendor.
In the Patent Publication U.S. Pat. No. 6,427,234 B1 “SYSTEM AND METHOD FOR PERFORMING SELECTIVE DYNAMIC COMPILATION USING RUNTIME INFORMATION” by Chambers et al. a system and method for performing selective dynamic compilation using runtime information is disclosed. The disclosed system implements a declarative; annotation based dynamic compilation and contains a sophisticated form of partial evaluation binding-time analysis (BTA), including program-point-specific poly-variant division and specialization, and dynamic versions of traditional global and peephole optimizations. The system provides policies that govern the aggressiveness of specialization and caching. It allows these policies to be declaratively specified, enabling programmers to gain fine control over the dynamic compilation process. It also enables programmers to specialize programs across arbitrary edges, both at procedure boundaries and within procedures, and to specialize programs based on evaluation of arbitrary compile-time and runtime conditions. To achieve a different compiled result source files are changed. Such a source code modification has to be avoided.
In the Patent Publication U.S. Pat. No. 6,453,465 B1 “METHOD AND SYSTEM FOR COMPILING SOURCE CODE CONTAINING NATURAL LANGUAGE INSTRUCTIONS” by Klein a system and method for compiling source code comprising natural language declarations, natural language method calls, and natural language control structures into computer-executable object code is disclosed. The system and method allow the compilation of source code containing both natural language and computer language into computer-executable object code. The system and method use a component database, containing components and associated natural language instructions, to select one or more components having an instruction declaration associated with the natural language instruction. A solution manager is used to resolve ambiguities inherent in the use of natural language instructions in the source code. Although a knowledge base is used in combination with specially written source code to influence the generation of machine code the disclosed system and method are pertained to specially written source files and do not pertain to the code generation process (build) itself.
In the Patent Publication U.S. Pat. No. 5,956,513 “SYSTEM AND METHOD FOR AUTOMATED SOFTWARE BUILD CONTROL” by McLain Jr. an automated computer program application, called an automated build control application, provides an improved tool for managing the software build process. The automated build control uses the specification of a programmer's original program files as input, and automatically identifies all header, include, and other shared library files, which eliminates coding of dependencies. The automated build control identifies embedded header files, such as those which are referenced in other header files. The automated build control identifies duplicate headers so future builds can be expedited. The automated build control ensures all necessary source modules are located and available for compilation, prior to compilation. The automated build control performs comparisons of date/time stamps and identifies what source modules require recompilation. Essentially, the automated build control evaluates the compiling and linking processes prior to performing them, thus detecting any potential errors or conflicts before any time and effort is wasted. The disclosed tool for building software is similar to what most modern development tools like Microsoft visual Studio or Eclipse do when generating software by examining source files and determining dependencies. Nevertheless the disclosed system and method make no reference to a knowledgeable or of affecting an existing program build process without intervention.
The technical problem underlying the present invention is to provide a method for program building and a system for program building, which are producing optimized code to suit particular needs of a vendor and to solve the above mentioned shortcomings and pain points of automated program build processes according to prior art.
According to the present invention this problem is solved by providing a method for program building having the features of claim 1, a system for program building having the features of claim 7, a data processing program for program building having the features of claim 14, and a computer program product for program building having the features of claim 15. Advantageous embodiments of the present invention are mentioned in the subclaims.
Accordingly, in an embodiment of the present invention a method for program building uses predefined source files and predefined build scripts comprising a sequence of build commands; wherein each build command comprises an origin command line interpretable by an operating system and addressed to at least one compiling tool; wherein each command line comprises a source file name and/or a destination file name and/or a program name and/or an indication of at least one action to be performed by the at least one addressed compiling tool and/or an option related to a corresponding action to be performed; wherein each origin command line is parsed to identify components of the corresponding build command; wherein each identified component is evaluated against rule sets containing conditions and instructions to change the origin command line, wherein matching rule sets are processed to generate at least one resultant command line interpretable by the operating system, wherein processing of the at least one resultant command line by the operating system produces an intermediate output file recursively processed by at least one additional command line and/or a final output file interpretable by a target hardware platform.
In further embodiments of the present invention, matching rule sets are processed to run a script triggered by at least one component of the origin command line, wherein running of the script generates at least one resultant command line.
In further embodiments of the present invention, the script is a pre-compile script and/or a post-compile script.
In further embodiments of the present invention, to generate the at least one resultant command line components of a corresponding origin command line are replaced, deleted or appended.
In further embodiments of the present invention, the rule sets comprise predicate conditions and command line component modification instructions and runtime script declarations, wherein a Cartesian product is formed based on the input dimensions and the rule sets stored in a knowledge database, wherein for each command line component satisfying the predicate conditions of a rule set corresponding command line component modifications are applied and corresponding scripts are invoked at defined points in program flow.
In further embodiments of the present invention, the rule sets comprise predicate conditions and command line component modification instructions and runtime script declarations, wherein a Cartesian product is formed based on said input dimensions and said rule sets stored in a knowledge database, wherein for each command line component satisfying said predicate conditions of a rule set corresponding command line component modifications are applied and corresponding scripts are invoked at defined points in program flow.
In another embodiment of the present invention, a system for program building comprises a resource pool with predefined source files and predefined build scripts comprising a sequence of build commands; a unified build frontend and at least one compiling tool, wherein each build command comprises an origin command line interpretable by an operating system and addressed to at least one compiling tool; wherein the unified build frontend performs the steps of: Receiving the predefined source files and the sequence of build commands from the operating system, wherein each command line comprises a source file name and/or a destination file name and/or a program name and/or an indication of at least one action to be performed by the at least one addressed compiling tool, and an option related to a corresponding action to be performed; loading a control file stored in a knowledge database containing rule sets with conditions and instructions in order to modify the origin command line; parsing each origin command line to identify components of the corresponding build command; wherein each identified component is evaluated against the rule sets, processing matching rule sets to generate at least one resultant command line interpretable by the operating system, and outputting the resultant command line to the operating system, wherein the operating systems processes the at least one resultant command line and produces an intermediate output file recursively processed by at least one additional command line and/or a final output file interpretable by a target hardware platform.
In further embodiments of the present invention, the unified build frontend processes the matching rule sets to initiate a script run on the operating system triggered by at least one component of the origin command line, wherein running of the script generates at least one resultant command line.
In further embodiments of the present invention, the script is a pre-compile script and/or a post-compile script.
In further embodiments of the present invention, the unified build frontend generates the at least one resultant command line by performing at least one of the following actions: Replacing, deleting and appending components of a corresponding origin command line.
In further embodiments of the present invention, the at least one compiling tool is a program invoked by the operating system during processing of the at least one resultant command line preferably a high level language compiler or a program linker.
In further embodiments of the present invention, the rule sets comprise predicate conditions and command line component modification instructions and runtime script declarations, wherein the unified build frontend forms a Cartesian product based on the input dimensions and the rule sets stored in the knowledge database.
In further embodiments of the present invention, the unified build frontend applies corresponding command line component modifications for each command line component satisfying the predicate conditions of a rule set and invokes corresponding scripts at defined points in program flow.
In another embodiment of the present invention, a data processing program for execution in a data processing system comprises software code portions for performing a method for program building when the program is run on the data processing system.
In yet another embodiment of the present invention, a computer program product stored on a computer-usable medium, comprises computer-readable program means for causing a computer to perform a method for program building when the program is run on the computer.
The major aspect of the introduced invention is a smart means to modify the behavior of an automated program build process. The modification may include but is not limited to replacing; deleting or appending components of an origin command line of a corresponding build command, changing order or type of used compiling tools, or running a pre-compile script or a post compile script triggered by at least one component of the origin command line. Whereby smart, is here defined as making decisions by evaluating input parameters and environmental conditions in correlation to rules stored within a knowledge database.
All in all, embodiments of the present invention are able to changing the SAP program build results without changing SAP build scripts and introduce a compiler, linker, and tool replacement wrapper that change the characteristics of the program build environment without modifying the existing build scripts or input files. Additionally generic ‘rules’ stored in a knowledge base describe how the program build environment changes dynamically. The rule selection is based on the program build environment, the target hardware platform, and components of the origin command line of a corresponding build command like source and destination file names, program name, and an indication of at least one action to be performed, and arbitrary predicates of the rule set. The change could be replacing, deleting or appending components of an origin command line create and/or pre-processing or post-processing of scripts to generate the resultant command line processed by the operating system to produce an intermediate output file recursively processed by at least one additional command line, or a final output file interpretable by the target hardware platform.
Advantageously, embodiments of the present invention offer smart command line component mutation, process control, and script injection also for compiler invocation. The essence of the invention is the intelligent selection of command line component mutation instructions and selection of scripts.
One instance of the invention comprises of a unified build frontend, or front end replacement, that selectively mutates command line components and conditionally executes pre- and post-processing scripts before and after program building. The most significant portion of the invention is the smart condition determination and evaluation based on program building environment, target hardware platform and command line components. The primary benefit of the invention is a means to selectively modify command line components and to execute processing scripts in the program build process before source code to machine code compiling occurs, without having to modify invoking scripts or build process control files known as make files in the industry.
When redirecting generic program invocation through the invention, the invention provides a smart mechanism to mutate program invoking commands and additionally provides a mechanism to run scripts before and after underlying program invocation. By using the invention as a front-end invocation replacement for compiler and linker commands, a build process for generating software can be dramatically influenced without having to actually modify build scripts, e.g. make files, used to control the process. One such use of this facility is the generation of highly optimized profiled software wherein the generation of such would require special command options and tools and wherein the original build scripts were not written with this sort of optimization in mind. Another use of such a facility is the replacement of one compiler vendor for another wherein the build scripts contain vendor specific options. Another use of such a facility is the ability to selectively reduce optimization of particular modules when one vendor's compiler generates code that violates the original intentions of the source code.
The prior art method of determining input parameters to a compiler is by way of pre-selected parameters or by way of explicit conditional logic within invoking scripts or build process control files (make files). The practice of inserting an intermediate front-end tool to invoke an underlying tool is common; but a smart command line component mutation based on a knowledge base is not.
The prior art method of running scripts before compilation involves running the compiler from within a script or make-file. Within a script or make-file, commands can be issued before and after invoking the compiler. The invention here reverses this process; instead of the script running the compiler, the unified build frontend can run a script from within its own process. The infrastructure to intelligently select when, how and under what conditions to process script commands by the unified build frontend makes this feasible.
Embodiments of the present invention intercept each call to the compiling tools during the kernel build process and modify the command line components that are passed to the compiling tools, if needed. The unified build frontend is a direct invocation replacement for the compiler and allows the operating system to call the unified build frontend without the need to change anything other than a platform specific initial configuration file. The unified build frontend is smart and understands the intent of each program build step and—by way of a knowledge base—can be instructed to generate code that is very different than code that would have been generated by a standard build process.
Embodiments of the present invention allow dynamic modification of program build commands within a long sequence of build commands similar to those of originating from program make scripts. The original program make scripts are not modified and the instructions directing the dynamic modification of the program build commands are stored in a knowledge data base.
Further embodiments of the present invention provide the ability to use special tools to compile specific parts of the used kernel to improve performance or integrity. Another example is the ability to instruct the compiler to generate alternative code; when it is determined that either; a module doesn't lend itself to be optimized in a particular fashion, or a compiler abnormality (bug) causes the compiler to generate invalid code.
The above, as well as additional purposes, features, and advantages of the present invention will become apparent in the following detailed written description.
A preferred embodiment of the present invention, as described in detail below, is shown in the drawings, in which
Referring to
According to the present invention the unified build frontend performs 12 the steps of: Receiving the predefined source files and the sequence of build commands from the operating system 7; loading a control file 30 stored in a knowledge database 5 containing rule sets 32 with conditions 38 and instructions in order to modify said origin command line 20; parsing each origin command line 20 to identify components 22, 24, 25, 26, 28 of the corresponding build command; wherein each identified component 22, 24, 25, 26, 28 is evaluated against the rule sets 32, processing matching rule sets to generate at least one resultant command line interpretable by the operating system 7, and outputting the resultant command line to the operating system 7, wherein the operating system 7 processes the at least one resultant command line and produces at least an intermediate output file recursively processed by at least one additional command line, or a final output file interpretable by a target hardware platform 50.
The unified build frontend 12 provides additional or alternative processing before and/or after a compiling process by injecting at least one script 40. Therefore the unified build frontend 12 processes the matching rule sets to initiate a script 40 run on the operating system 7 triggered by at least one component 22, 24, 25, 26, 28 of the origin command line 20, wherein running of the script 40 generates at least one resultant command line. The script 40 is a pre-compile script, or a post-compile script, for example.
In the following, embodiments of the present invention are explained with respect to the unified build frontend 12 employed as compiler frontend. Therefore calls to the compiling tool 10 are substituted by calls to the unified build frontend 12 referred to unified_cc_ld in some of the following examples. The replacement can be accomplished either manually, by way of aliases, or by directing calls to the unified build frontend 12 (unified_cc_ld) through path or file system link (file system re-direction).
Referring to
The essence of the invention is the intelligent selection of command line component or input parameter mutation instructions and selection of scripts 40. In the shown embodiment of the present invention, the command line component 22, 24, 25, 26, 28 or input parameter mutation instructions and script selection is based on a number of dimensions like build operation, source file name(s) 22, destination file name(s) 24, program name 25, action(s) 26 to be performed, option(s) related to the action(s) 26 to be performed, abstract predicate condition(s) 38 and file system directory path, e.g. current working directory, source file path, etc.
The above dimensions are deciphered from the origin command line 20 or input parameters and the current program build environment 3. The invention also comprises the knowledge database 5 containing the rule sets 32. A rule set 32 consists of both the predicate conditions 38, i.e. when the rule should be applied, and the command line component or input parameter mutation instructions 34 also containing selection and application rule and runtime script declarations. The XML syntax, for example, is well suited to compose the knowledge database 5. A Cartesian product of the input dimensions with the rule sets 32 of the knowledge database 5 is formed. For each command line component 22, 24, 25, 26, 28 satisfying the rule's predicate conditions 38; the rule's command line component or input parameter mutation instructions 34 are applied to the command line components 22, 24, 25, 26, 28 or input parameters, and the scripts 40 are invoked at the defined points in the program flow.
Referring to
Still referring to
The unified build frontend 12 reads a control file 30, in step S110. In the shown instance of the invention, the control file 30 is written in XML format. The control file 30 contains two basic components like the predicates, i.e. a specification of condition when a parameter mutation should be applied, and a list of option overrides 34, i.e. descriptions of how command line components 22, 24, 25, 26, 28 or input parameters are to be mutated, e.g. added, replaced, or deleted.
Some compiling tools 10 are capable of more than code generation. Compiling tools 10 may preprocess a macro language; generate machine instructions, link modules containing machine instructions together as a large module, e.g. library or archive, shared module, or program. In step S120, the type of operation may be determined by information of the environment 3, the origin command line 20, or content of source files specified in the origin command line 20, e.g. source code, machine code, archive file, etc.
Referring to
An override set 32 may contain a number of independent option overrides 34, i.e. command line component or input parameter mutation descriptions. In subroutine S220, the unified build frontend 12 iterates over the option overrides 34. This corresponds to OptionList in the corresponding parameter mutation control file shown in
If the override condition doesn't match, the next option index (j) is incremented in step S350. If the option index matches the number of options, in step S360, the option iteration is complete; otherwise the next option is processed in subroutine S300.
In subroutine S215, an option override may consist of one of three actions: Delete option, in step S322, replace option, in step S332, or append option in step S344. If the action recognized in step S320 is ‘Delete’, the option is simply removed from the options that will be passed to the underlying compiling tool 10, in step S322. If the action recognized in step S330 is ‘Replace’, the option is replaced by a value formed by the override's rule in step S332. In one instance of the present invention, the override rule may be an expression statement containing literals and variables. The variables may be text segments of the original option. If the action recognized in step S340 is ‘Append’, the number of options is increased by one in step S342, and in step S344 an option is added by a value formed by the override's rule in a fashion similar to step S332.
The next option index (j) is incremented, in step S350. If the option index matches the number of options, in step S360, the option iteration is complete; otherwise the next option is processed in subroutine S300.
If the option iteration is complete, the next override index (i) is incremented in step S230, shown in
If the override iteration is complete, the next set index (k) is incremented in step S250. If the set index matches the number of override sets, in step S260, the command line component or input parameter mutation is complete; otherwise the next override set is processed in step S210.
In one instance of the invention, the knowledge database 5 used to describe how and under what conditions command line components 22, 24, 25, 26, 28 or input parameters are mutated, is described within an XML formatted control file 30. XML is extended Markup Language, and due to its adeptness for describing items, sets and groups, is well suited for describing the contents of a knowledge database 5 for an instance of the invention.
In reference to
A set of specification rules for an instance of the invention used in program generation may comprise “Compile”, “Library”, “Archive”, “Shared” and/or “Program” as BuildMode; “Replace”, “Delete” and/or “Append” as OptionAction, for example.
Referring to
Referring to
In step S110, the unified build frontend 12 reads a control file 30. In the shown embodiment of the present invention, the control file 30 is written in XML format. The control file 30 contains two basic components, the predicates, i.e. a specification of condition 38 when a script 40 should run; and a script specification 36, i.e. a pointer to the script 40 or the script 40 itself.
Some compiling tools 10 are capable of more than code generation. Compiling tools 10 may preprocess a macro language; generate machine instructions, link modules containing machine instructions together as a large module, e.g. library or archive, shared module, or program. In step S120, the type of operation may be determined by environment 3, command line components 22, 24, 25, 26, 28 or input parameters, or content of source files specified in the command line components 22, 24, 25, 26, 28 or input parameters, e.g. source code, machine code, archive file, etc.
Referring to
In an operating system, where new processes are spawned rather than forked (e.g. Microsoft Windows), the spawned child would receive enough information to be able to complete steps S410 to S430, as though the child was a result of a fork operation. The child process is necessary because the script 40 that may be run in step S420 must run in a different process than the parent, because after the compile operation in step S430 is finished, the parent must regain control to execute a post-compile script, in step S460.
Referring to
In embodiments of the present invention, the name of the unified build frontend 12 itself is considered an input parameter. If the unified build frontend tool 12 is named unified_cc_ld_underlying_tool_name then the unified build frontend tool 12 deciphers the underlying tool to be ‘underlying_tool_name’ and considers this as the first input argument. This provides an additional means for the unified build frontend tool 12 too, to determine what task it is intended to perform. For example, a unified_cc_ld_CC is a c++ code compiler and unified_cc_ld_ld is a linker. Before running scripts to perform a software build the compile command CC is aliased to unified_cc_ld_CC and the linker command ld is aliased to unified_cc_ld_ld.
In a typical instance of the invention, both command line component or input parameter mutation and compiler script injection are performed by the same unified build frontend 12. Due to the complementary XML tag names, one XML control file 30 can contain both command line component or input parameter mutation instructions and before and after script declarations. When processing command line component or input parameter mutation and script injections, the command line component or input parameter mutation would typically be performed prior to spawning a new process in which the before script and the underlying compiling tool 10 would be invoked, shown as dashed box S200 to S360 in
In some situations, it could be desired that a particular module or program be built with different options, an optimized and a debug-able version of a program. One means for this is an iteration process control feature. The XML control file 30 contains a provision to specify the number of times a particular compile step should be performed. The XML control file 30 also has a provision to specify that certain sections of the control file are only valid for a particular iteration. Appending a hash ‘#’ and an integer (n) to the first option or program to be invoked, causes the program to be issued n times. Appending an ampersand ‘&’ to the first option or program to be invoked causes the program to be issued in the background in parallel.
The example shown in
Embodiment of the present inventive can be implemented as an entirely software embodiment, or an embodiment containing both hardware and software elements. In a preferred embodiment, the present invention is implemented in software, which includes but is not limited to firmware, resident software, microcode, etc.
Furthermore, the present invention can take the form of a computer program product accessible from a computer-usable or computer-readable medium providing program code for use by or in connection with a computer or any instruction execution system. For the purposes of this description, a computer-usable or computer-readable medium can be any apparatus that can contain, store, communicate, propagate, or transport the program for use by or in connection with the instruction execution system, apparatus, or device.
The medium can be an electronic, magnetic, optical, electromagnetic, infrared, or semiconductor system (or apparatus or device) or a propagation medium. Examples of a computer-readable medium include a semiconductor or solid state memory, magnetic tape, a removable computer diskette, a random access memory (RAM), a read-only memory (ROM), a rigid magnetic disk, and an optical disk. Current examples of optical disks include compact disk—read only memory (CD-ROM), compact disk—read/write (CD-R/W), and DVD. A data processing system suitable for storing and/or executing program code will include at least one processor coupled directly or indirectly to memory elements through a system bus. The memory elements can include local memory employed during actual execution of the program code, bulk storage, and cache memories which provide temporary storage of at least some program code in order to reduce the number of times code must be retrieved from bulk storage during execution. Input/output or I/O devices (including but not limited to keyboards, displays, pointing devices, etc.) can be coupled to the system either directly or through intervening I/O controllers.
Network adapters may also be coupled to the system to enable the data processing system to become coupled to other data processing systems or remote printers or storage devices through intervening private or public networks. Modems, cable modems, and Ethernet cards are just a few of the currently available types of network adapters.
Kass, Eric R., Sell, Stefan B.
Patent | Priority | Assignee | Title |
Patent | Priority | Assignee | Title |
5956513, | Aug 07 1997 | Verizon Patent and Licensing Inc | System and method for automated software build control |
6427234, | Jun 11 1998 | Washington, University of | System and method for performing selective dynamic compilation using run-time information |
6453465, | Oct 16 1998 | Method and system for compiling source code containing natural language instructions | |
7340726, | Aug 08 2003 | SYNOPSIS, INC; Synopsys, Inc | Systems and methods for performing static analysis on source code |
20020199170, | |||
20030163799, |
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