Abstract:
The present invention provides a system and method for optimizing a cache that substantially eliminates reduces the disadvantages of previously developed cache management systems. More particularly, embodiments of the present invention provide a system of optimizing a cache by polling cached assets with a frequency dependent of the relative activity of a cached asset. An embodiment of the method of the system includes the steps of: (i) polling a cached asset according to a first schedule to determine if the cached asset has been active within a first predefined period of time; (ii) if the cached asset has not been active, polling the cached asset according to a second schedule to determine if the cached asset has been inactive for at least a second predefined period of time; (iii) demoting the cached asset to less active status; and (iv) if the cached asset has been inactive for at least within the second predefined period of time, demoting the cached asset to inactive status. In one embodiment of the present invention, if the cached asset has been active within the second predefined period of time, the cached asset can again be polled according to the first frequency. The frequency with which the cached asset can be polled according to the first and second schedule can be a matter of optimization. Polling according to the first schedule can occur at a greater frequency than polling according to the second schedule. Thus, more active assets can be polled more often than less active assets.

Description:
TECHNICAL FIELD OF THE INVENTION  
         [0001]    This invention relates generally to cache management. More particularly, the present invention relates to methods and systems for the optimization of system resources during cache management. Even more particularly, the present invention relates to a system and method for polling assets in a cache at different frequencies depending upon the relative activity of the assets.  
         BACKGROUND OF THE INVENTION  
         [0002]    A cache is essentially a buffer between a high-speed system and a low-speed system. Caches are becoming increasingly important for use in computers and computer systems in which there may be several devices running at different speeds. Even in a single computer, caches may be necessary to optimize performance. For example, in the common desktop personal computer (“PC”), there are typically many different layers or levels of cache. Level 1 or primary cache is the fastest cache in the PC and is typically built into the central processing unit (“CPU”) (level 1 cache is also called “internal” cache as it is integrated directly with the CPU). Although this cache is generally very small (e.g., under 100 KB) it runs at or near the CPU speed. Level 1 cache is used to store the highest priority and most often accessed instructions. Because the most commonly used instructions are stored in Level 1 cache, that runs at or near the same speed as the CPU, they can be accessed quickly and easily by the CPU.  
           [0003]    While it may be desirable to store all commonly used instructions in such a fast memory, such memory is prohibitively expensive. Therefore, other commonly used instructions can be stored in level 2 cache. Level 2 cache can typically store a greater number of instructions than level 1 cache (e.g., can store more than 1 MB) but is slightly slower. If an instruction cannot be found in the level one cache, the CPU will look for the instruction in the level 2 cache. In addition to storing instructions in level 1 and level 2 cache, commonly accessed instructions can also be stored in system RAM, which is slightly slower than level 1 or level 2 cache, but is significantly faster than a hard disk drive or floppy disk drive, where instructions would otherwise be stored.  
           [0004]    By storing commonly accessed instructions in various levels of cache, a computer&#39;s performance can be significantly increased. This is because during the execution of a program the same instructions are typically accessed repeatedly. By storing the most accessed instructions in the highest speed cache (e.g., level 1 cache) and so on, the CPU can access the instructions at the speed of the respective cache rather, than at the speed of, for example, a relatively slow disk drive. Thus, the use of various levels of cache can significantly enhance computer performance.  
           [0005]    Caches are not only useful to buffer instructions between internal components of a computer, but can also be used to buffer files exchanged between systems that have different access speeds. For example, caching is a commonly employed tool for displaying web pages over the Internet. When a user accesses a web page via the Internet, the speed at which a page can be downloaded to his/her computer is typically dictated, not by processor speed or available system RAM, but instead by the speed of the connection between the user&#39;s computer and the web server at which the web page resides. In order to increase the speed at which pages are downloaded, many Web browsers can cache commonly downloaded web pages or components of web pages. For example, the users Web browser could cache images from the web page that are repeatedly accessed, such as buttons or banners, on the user&#39;s hard disk drive. When the user attempts to download the same web page or related web pages that use the same buttons and/or banners, the buttons or banners can be downloaded from the hard disk drive rather than from the Web server (i.e., over the much slower network connection), thereby significantly decreasing the download time.  
           [0006]    Similarly, a cache can be used to increase the speed with which files on a database (“database assets”) can be accessed and modified. In current systems, when a user requests a database asset from a database, a copy of the database asset is sent to the user&#39;s computer and can be cached on the user&#39;s hard disk drive. When the user accesses or modifies the database asset, he/she, in some applications, accesses the cached file on the hard drive and not the database asset stored on the database. Again, because the file is accessed from the hard disk drive and not over a relatively slow network connection, the file can be accessed and modified much more quickly. When the user has completed work on the cached file, the cached filed can be reconciled or synchronized with the file on the database. For example, in the manner described in related United States patent application “System and Method for Synchronization of a File in a Cache,” filed on ______, 2001, by inventors David Thomas and Scott Wells (the “Synchronization Application”) which is hereby fully incorporated by reference.  
           [0007]    For file caches (e.g., caches that contain files rather than instructions), particularly for those associated with databases and/or the Internet, cache management presents several difficulties. One such difficulty is that if many files are cached, the memory that stores the cache can eventually become saturated (i.e., reach capacity). Therefore, a cache management program must be implemented to delete files from the cache. In current systems, the cache management program is typically integrated into the application or program that actually accesses files from the cache. Thus for example, a typical database synchronization program (e.g., a program that synchronizes cached files on a user&#39;s computer with database assets in a database) or Internet browser will have a cache management aspect to manage the cache of database or Internet files on the user&#39;s computer. In these systems, the cache management program generally maintains a list of cached files and periodically removes files from the cache. These systems, however, have significant shortcomings because the cache management portion of this software must be subsumed by another program. In order to manage the cache, the cache management program must receive detailed contextual information, such as when a particular file was last accessed or last modified from another portion of the same software program. Furthermore, synchronization programs are typically designed for use with only one application, limiting the usefulness of a cache management program associated with the synchronization program. Thus, the cache management portion can typically only manage files associated with the overall program of which the cache management program is a part.  
           [0008]    Additionally, current cache management systems generally do not optimize system resources. Typically, the cache management system will review the list of cached files on a predetermined frequency. As the list of cached files grows, reviewing the list will take progressively longer. The current cache management systems, however, do not account for the fact that some files in the cache may be less active than others. Therefore, reviewing less active files can consume as many, if not more, system resources as reviewing active files.  
         SUMMARY OF THE INVENTION  
         [0009]    The present invention provides a system and method for optimizing a cache that substantially eliminates or reduces the disadvantages of previously developed cache management systems. More particularly, embodiments of the present invention provide a method and system for optimizing a cache by polling cached assets with a frequency that can be dependent on the relative activity of the cached asset being polled. One embodiment of the method of the present invention includes the steps of: (i) polling a cached asset according to a first schedule to determine if the cached asset has been active within a first predefined period of time; (ii) if the cached asset has not been active for at least the first predetermined period of time, demoting (e.g., giving the asset a status so that the asset is polled less frequently or not at all) the cached asset to less-active status and polling the cached asset according to a second schedule to determine if the cached asset has been active within a second predefined period of time; and (iii) if the cached asset has not been active for at least the second predefined period of time, demoting the cached file to an inactive status. According to one aspect of the present invention, a cached asset that has been demoted to inactive status can be removed from the cache. In one embodiment of the present invention, if the cached asset has been active within the second predefined period of time, the cached asset can again be polled according to the first frequency (e.g., can be promoted to active status). The frequency with which the cached asset can be polled according to the first and second schedule can be a matter of optimization. Polling according to the first schedule can occur at a greater frequency than polling according to the second schedule. Thus, more active files can be polled more often than less active files.  
           [0010]    Embodiments of the present invention provide a technical advantage over previously developed cache management systems by providing the ability to manage a cache without detailed contextual information about the cached assets. Thus, the present invention can be implemented to more efficiently manage a cache containing a large variety of asset types.  
           [0011]    Embodiments of the present invention provide another advantage by being able to manage a cache without being subsumed by another software program. Thus, the present invention can be used to manage a cache of assets that are accessed by multiple software applications.  
           [0012]    Yet another advantage provided by embodiments of the present invention is the ability to poll active assets more frequently than less active assets, thereby saving significant system resources and improving performance. This can also reduce latency between changes to an asset at the cache and updates to a corresponding asset on another system (e.g., a database).  
       
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0013]    A more complete understanding of the present invention and the advantages thereof may be acquired by referring to the following description, taken in conjunction with the accompanying drawings in which like reference numbers indicate like features and wherein:  
         [0014]    [0014]FIG. 1 illustrates a computer network that can utilize a cache manager according to one embodiment of the present invention;  
         [0015]    [0015]FIGS. 2A through 2C provide diagrammatic representations illustrating the polling of a cache according to one embodiment of the present invention; and  
         [0016]    [0016]FIG. 3 is a flow chart illustrating one embodiment of a method for managing a cache according to the present invention.  
     
    
     DETAILED DESCRIPTION OF THE INVENTION  
       [0017]    Preferred embodiments of the present invention are illustrated in the FIGUREs, like numerals being used to refer to like and corresponding parts of the various drawings.  
         [0018]    Embodiments of the method and system of the present invention provide the capability to manage and optimize a cache. In particular, embodiments of the present invention provide the ability to survey or poll assets in a cache that have recently been active at a higher frequency, while polling those assets in the cache that have been less active at a lower frequency. By polling relatively inactive assets less frequently, significant system resource savings can be achieved.  
         [0019]    For the sake of explanation, embodiments of the present invention will be described in the context of managing cached files that are associated with assets in a database. However, this example is by no means limiting of the present invention as the present invention is equally applicable to managing a variety of cached digital assets including images, videos, audio files, documents, source code, compiled files and so on, in distributed or non-distributed systems.  
         [0020]    [0020]FIG. 1 illustrates a computer network  20  that can utilize a cache manager  16  operated in accordance with the teachings of the present invention to optimize cache  18 . Network  20  can include at least one client computer  22  and at least one server computer  24 . Client computer  22  and server computer  24  can be connected via a network  26 , which can comprise any wire or wireless network, including global computer networks such as the Internet. Client computer  22  can be a personal computer, a workstation, a wireless device, a laptop computer, or any other computing device operable to access data from a database. Client computer  22  can include a central processing unit  30  (“CPU”  30 ) connected to a computer-readable memory  32 . Memory  32  can comprise any combination of system RAM  33 , ROM and/or magnetic storage device(s), such as a hard drive. Furthermore, while in FIG. 1 memory  32  is shown to be connected locally to CPU  30  at client computer  22 , memory  32  need not be local and can be distributed between several devices. As noted earlier, embodiments of the present invention can also manage digital assets stored in a non-distributed system.  
         [0021]    Memory  32  can store a number of computer programs executable by a computer processor (e.g., CPU  30 ), including an operating system  34  having a file management system  35 , various applications  36  that can comprise software tools, such as word processing tools and other software tools known to those in the art. Memory  32  can also store a cache manager  16 . As would be understood by those of ordinary skill in the art, operating system  34  can provide a software platform upon which other programs, such as applications  36  and cache manager  16  run. File management system  35  can be used by operating system  34  to organize and keep track of files. In one embodiment of file management system  35 , file management system  35  can be a hierarchical file system that uses directories to organize files into a tree structure having various nodes to represent directories and files. Memory  32  can also include cache  18  which can contain cached versions of database assets, such as cached files  42 - 1  . . .  42 - 10 . As will be discussed in greater detail below, each cached file  42 - 1  . . .  42 - 10  can be a cached version, either modified or unmodified, of a database assets  43 - 1  . . .  43 - 10 , respectively. Client computer  22  can establish network communication through a standard network connection device  44 . Network connection device  44  can be any compatible network connection device that is known to those in the art. Again, while embodiments of the present invention are described in regard to managing cached files, those embodiments are not limiting of the scope of the present invention and, as would be understood by one of ordinary skill in the art, other embodiments of the present invention can manage other forms of cached assets.  
         [0022]    Server computer  24  can comprise standard server computer components, including a server network connection device  46 , a CPU  48 , and a primary and/or secondary memory  50 . Network connection device  46 , CPU  48  and memory  50  can be equivalent components to network connection device  44 , CPU  30  and memory  32  of client computer  22 . Memory  50  can store database management program  52 , which can be executable to carry out standard database functions, including receiving requests for data, retrieving the data, and returning the data to the requesting computer. Memory  50  can also include a database  54  which can comprise various database assets, such as database assets  43 - 1  . . .  43 - 10 . The database assets  43 - 1  . . .  43 - 10  can include a variety of different file types, including, but not limited to, text files, spreadsheet files, graphics files, audio, graphic html files, etc.  
         [0023]    It should be noted that the system architecture illustrated in FIG. 1 is exemplary only and is designed to give context to the embodiments of the present invention. However, various embodiments of cache manager  16  can be implemented with different architectures of client computer  22  and server computer  24 . Furthermore, while cache manager  16  will be discussed primarily in conjunction with managing a file cache for database files, embodiments of cache manager  16  can be used in any system that manages cached assets.  
         [0024]    Returning to FIG. 1, in operation, a user wishing to access a database asset (e.g., database asset  43 - 1 ) can establish a connection through a standard network application, as is known to those in the art, with a server (e.g., server computer  24 ) associated with the database (e.g., database  54 ) on which the database asset (e.g., database asset  43 - 1 ) is stored. Once the user has established a connection to server computer  24 , cache manager  16  can determine the contents of database  54  and can display a representation of the contents in, for example, a graphical user interface, or can enumerate the contents for display by an external graphical user interface. The user can select a database asset in which he/she is interested from the graphical user interface. When the user selects a database asset (e.g., database asset  43 - 1 ) by, for example, double clicking on the database asset in the graphical user interface, a request can be sent to server computer  24  for that database asset. Database management program  52  will receive the request, search database  54  for database asset  43 - 1 , retrieve database asset  43 - 1 , and communicate a copy of database asset  43 - 1  to client computer  22 . Typically, a copy of database asset  43 - 1  is also maintained on database  54 .  
         [0025]    Upon receiving the copy of database asset  43 - 1  at client computer  22 , cache manager  16  can save database asset  43 - 1  as a cached file  42 - 1  in memory  32 . In addition, cache manager  16  can associate cached file  42 - 1  with a particular connection (e.g., with a particular database) so that if the user is accessing multiple databases over multiple connections, cache manager  16  can keep track of the database from which database asset  43 - 1  was obtained. Cache manager  16  can also associate cached file  42 - 1  with a unique location on memory  32 . Assume, for example, that database asset  43 - 1  is the image file “myfile.jpg.” When the user requests myfile.jpg, cache manager  16  can request the file from server computer  24 . Database management program  52  can search database  54  for myfile.jpg, retrieve myfile.jpg, and send a copy of myfile.jpg to client computer  22 , while retaining a copy on database  54 . Cache manager  16  can receive myfile.jpg and associate myfile.jpg with database  54 . Cache manager  16  can also save myfile.jpg as cached file  42 - 1  in cache  18  and associate myfile.jpg with a unique location in memory  32 . As an example, cache manager  16  can store myfile.jpg on a hard disk drive as C:\cache\myfile.jpg. Over a period of time (for example, over a work day), the user may access many files from various databases. Thus, the size of cache  18  will continue to grow and the number of cached files can become extremely large.  
         [0026]    A user can access the cached files using application  36 , which can be any suitable application known in the art. As would be understood by those of ordinary skill in the art, when the user opens a cached file, application  36  will typically open the cached file, copy the cached file into system RAM  33 , and close the cached file. The user can then view or modify the copy of the cached file  42 - 1  stored in system RAM  33 . When the user modifies the cached file  42 - 1  (e.g. as resident in RAM  33 ) and saves the file, application  36 , can write the modification from RAM  33  back to cache  18  (e.g., can update cached file  42 - 1  in cache  18 ). As noted earlier, in prior art systems, cache manager  16  is typically subsumed by a particular application  36  such as a web browser. Therefore, cache manager  16  would have detailed knowledge of when a cached file  42  is written back to cache  18  (e.g., when cached file  42 - 1  is saved by application  36 ). However, there may be cases in which cache manager  16  cannot receive direct notification from application  36  or from file management system  35  that a cached file has been saved.  
         [0027]    The Synchronization Application discloses one embodiment of a system for synchronizing a database in which a cache manager is not subsumed by application  36  and can manage cached files that are associated with many different applications  36 . As described in the Synchronization Application, if the cache manager cannot receive direct notifications from file management system  35  or application  36  as to when a particular file is saved, the cache manager can poll the cached file to determine if the file has been modified within a specific period of time.  
         [0028]    While the Synchronization Application describes at least one system in which a cache manager  16  polls the cached file  42 - 1  to determine if changes have been made to cached file  42 - 1 , it should be understood that this is provided by way of example only and that the teachings of the present invention are generally applicable to any system in which polling of a cache occurs.  
         [0029]    As noted before, when an application  36  opens a cached file  42 , application  36  typically stores cached file  42 - 1  in system RAM  33  and closes cached file  42 - 1 . If cache manager  16  simply monitored cached file  42 - 1  for opening and closing, it would appear that cached file  42 - 1  was only open for a very short period of time (e.g., the amount of time it takes to copy cached file  42 - 1  into system RAM  33 ). Additionally, it is possible in many current applications  36 , such as Microsoft™ Word, to close a file but keep the application open. Thus, monitoring opening and closing of application  36  will not reflect modification to cached file  42 . Because cache manager  16  does not receive direct notifications of when a cached file  42  is saved from application  36  or file management system  35 , and because monitoring either the opening and closing of cached filed  42 - 1  or application  36  will not detect all modifications to cached file  42 - 1 , cache manager  16  can, as will be described in greater detail below, poll the cached files to determine if the cached files have been modified.  
         [0030]    In accordance with the teachings of the present invention, cache manager  16  can poll cached assets (e.g., cached files) stored in cache  18 . Cache manager  16 , for each file in cache  18 , can read a time stamp associated with the cached file to determine when the cached file was last accessed or modified. As would be understood by those of ordinary skill in the art, time stamps are attributes of the cached files stored by file management system  35  each time a file is accessed and/or saved. Cache manager  16  can poll files that have shown recent activities (e.g., the time stamp associated with the cached file indicated the cached file has been modified within a certain period of time) at a high frequency while polling those files that indicate less activity (e.g., cached files with associated time stamps that have not been modified for greater than a preset period of time) with lesser frequency. Because files that are less active are polled less frequently, client computer  22  can use fewer resources to poll cache  18  than if all the files were polled at the same frequency.  
         [0031]    [0031]FIGS. 2A through 2C provide diagrammatic representations illustrating the polling of cache  18  according to one embodiment of the present invention. Cache manager  16  can maintain a cache  18  of cached files (labeled  42 - 1  through  42 - 10 ) on memory  32 . Cache manager  16  can also maintain an active list  62  in memory  32  of cached files which have recently been active (e.g., have been accessed or modified within a first predetermined period of time, as will be described in greater detail below). As illustrated in FIG. 2A, active list  62  can include entries  64 - 1  through  64 - 10  corresponding to each cached file  42 - 1  through  42 - 10 . It is assumed, for the sake of explanation, that in FIG. 2A each cached file  42 - 1  through  42 - 10  has recently been active (has been accessed and/or modified within a first predetermined period of time) and therefore each file has an associated file entry  64  in active list  62 . This could occur, for example, if each file  42 - 1  through  42 - 10  had recently been opened, as might typically occur when an employee opens files from a database at the beginning of a work day. Whether a file is considered recently active or not can be, as will be discussed below, a matter of tuning and optimization.  
         [0032]    In operation, cache manager  16  can read active list  62  and poll files with associated file entries  64  at a predetermined frequency. During polling, cache manager  16  can read a time stamp from the file attributes associated with each file  42 - 1  through  42 - 10 . The time stamp can comprise a last-modified time stamp and/or a last-accessed time stamp. As would be understood by those of ordinary skill in the art, these time stamps are typically supplied by a file management system (e.g., file management system  35 ) whenever a file is opened or modified. Thus, each set of file attributes for a file can, in one embodiment of the present invention, include a last-modified and/or a last-accessed time stamp. Cache manager  16  can read the time stamps for each cached file  42 - 1  . . .  42 - 10  to determine if the file has either been accessed or modified within a first predetermined period of time. For example, cache manager  16  could read the time stamps associated with each cached file  42 - 1  . . .  42 - 10  to determine if each cached file  42 - 1  . . .  42 - 10  has either been modified or accessed within the last three hours. If a file has not been accessed or modified for at least the predetermined period of time (e.g., three hours), that file can be demoted to a less active status as shown in FIG. 2B.  
         [0033]    As illustrated in FIG. 2B, cache manager  16  can also maintain a less active file list  66  of less active files. If, for example, during polling based on active file list  62 , it is determined that files  42 - 6 ,  42 - 8 ,  42 - 9 , and  42 - 10  have not been accessed or modified for at least the first predetermined period of time (e.g., three hours), these files can be demoted to the less active list  66  as represented by the fact that file entries  64 - 4 ,  64 - 8 ,  64 - 9 , and  64 - 10  are now included in less active file list  66 . Because files listed in less active file list  66  have exhibited less activity, these files can be polled less frequently (e.g., according to a second schedule) than files in active list  62 . Thus, for example, cache manager  16 , in accordance with FIG. 2A, could poll cached files  42 - 1 ,  42 - 2 ,  42 - 3 ,  424 ,  42 - 5 , and  42 - 7 , which are represented in active file list  62  of FIG. 2B, every thirty seconds, and poll cached files  42 - 6 ,  42 - 8 ,  42 - 9 , and  42 - 10 , which are represented in the less active file list  66  of FIG. 2B, every three minutes. If it is determined, based on the file stamp(s) (e.g., either the last-accessed or last-modified file stamp) that a file represented in the active file list  62  has been inactive for at least a first predetermined period of time (e.g., three hours), this file can be demoted to less active file list  66 . Files represented in less active file list  66  can be polled less frequently than those represented in active file list  62 .  
         [0034]    For example, in FIG. 2B, cached files  42 - 6 ,  42 - 8 ,  42 - 9  and  42 - 10  can be polled less frequently than cached files  42 - 1 ,  42 - 2 ,  42 - 3 ,  424 ,  42 - 5 , and  42 - 7 . When these less-active cached files are polled, the time stamp(s) for each file can be read to determine if a file has been accessed or modified within a second predetermined period of time. If a cached file from less active file list  66  has remained inactive (e.g., has not been accessed or modified) for at least the second predetermined period of time (e.g., has been less-active for at least five hours), as determined from the time stamp(s) associated with the cached file, the cached file can be removed from cache  18  or, alternatively, can be demoted to a non-active file list  68  (as shown in FIG. 2C). Contrasting FIGS. 2C and 2B, files  42 - 5  and  42 - 7  have been demoted to less active status (i.e., file entries  64 - 5  and  64 - 7  are included in less active file list  66 ) and files  42 - 9  and  42 - 10  have been demoted to non-active status, (i.e., file entries  64 - 9  and  64 - 10  are included in non-active file list  68  because cached files  42 - 9  and  42 - 10  have been inactive for longer than the second predetermined period of time). Files listed in non-active file list  68  (e.g., files  42 - 9  and  42 - 10 ) can continue to be polled at an even lower frequency than those in less active file list  66 . The files represented in non-active file list  68  can be deleted when they have been inactive for greater than a third predetermined period of time or when non-active file list  68  exceeds a certain size.  
         [0035]    It should be noted that while FIGS.  2 A- 2 C depict three layers of polling (e.g., active, less active, and non-active), there can be more layers, depending on the size of cache  18  and the system requirements of client computer  22 . It should be further noted that between FIGS. 2B and 2C, file entry  64 - 6  has been promoted from less active file list  66  to active file list  62 . Promotion from less active status to active status can occur automatically or when polling indicates that a file has been accessed or modified during the second predetermined period of time. Automatic promotion can occur if cache manager  16  monitors cached files  42 - 1  through  42 - 10  and determines that a cached file (e.g. cached file  42 - 6 ) has been opened. This might occur, for example, if a user opened cached file  42 - 6  through a file management system  35  (e.g. by double clicking on the file in the Windows™ Explorer interface). Alternatively, cache manager  16  can poll cached file  42 - 6  and if the last accessed and/or last modified time stamp(s) have changed during the second predetermined period of time, cache manager  16  can promote cached file  42 - 6  to active status.  
         [0036]    The frequency with which active files (e.g., those represented in active file list  62 ) and less active files (e.g., those represented in less active file list  66 ) are polled can, in one embodiment of the present invention, be determined as a matter of optimization. Typically, less active files will be polled less often than active files. By doing so, significant system resource savings can be achieved. This occurs because during the highest frequency polling, cache manager  16  only has to poll those files that have recently been active, while less active files can be polled less frequently. If the polling frequency for either active files or for less active files increases, more system resources-are required because each cached file  42  in cache  18  must be reviewed more often. However, if the polling frequency of either active files or less active files is too long, latencies can occur (e.g., a period of time may elapse before a file is promoted to active status). In one embodiment of the present invention, the polling interval associated with active files can be on the order of seconds while the polling interval associated with less active files can be on the order of minutes.  
         [0037]    In addition to adjusting the polling interval to optimize system resources, the amount of time (e.g., the first and/or second predetermined periods of time) required to trigger demotion to a lower level status (e.g., from active status to less active status, or from less active status to non-active status) can also be tuned to optimize system performance. If these predetermined periods of time (e.g., the first predetermined period of time or second predetermined period of time) are too long, each polling list (e.g., active file list  62  and less active file list  66 , respectively) can become too large, thus requiring significant system resources to poll. However, if the first and/or second periods of time are too short, files may be prematurely demoted. Therefore, polling frequencies and the periods of time required to demote files from one status to another can be tuned based on system resources to optimize performance.  
         [0038]    [0038]FIG. 3 is a flow chart illustrating one embodiment of a method for managing a cache according to the present invention. At step  80 , cache manager  16  can poll a recently active file (e.g., cached file  42 - 1 ) according to a first schedule or polling frequency. During polling, cache manager  16  can read a time stamp associated with the file. As would be understood by those of ordinary skill in the art, the time stamps can be provided by file management system  35  as attributes of the cached files. At step  82 , cache manager  16  can determine if, for example, cached file  42 - 1  has been accessed or modified within a first predetermined period of time. For example, cache manager  16  can determine if cached file  42 - 1  has been active within the last thirty minutes by determining the last time, according to the time stamp(s) provided by file management system  35 , that cached file  42 - 1  was either accessed or modified. If at step  82  it is determined that cached file  42 - 1  has been accessed or modified within the first predetermined period of time, cache manager  16  can continue to poll cached file  42 - 1  according to the first polling frequency. If, however, at step  82  cache manager  16  determines that cached file  42 - 1  has not been active for at least the first predetermined period of time, cache manager  16  can demote cached file  42 - 1  to less active status and, at step  84 , poll cached file  42 - 1  according to a second polling frequency (e.g., second schedule). Typically, for the sake of optimization, the second polling frequency will result in polling of files less often than the first polling frequency.  
         [0039]    Cache manager  16 , at step  84 , can poll cached file  42 - 1  according to the second polling frequency and determine if cached file  42 - 1  has been modified and/or accessed, according to the last-modified or last accessed time stamp(s), during the second predetermined period of time. Cache manager  16  can also determine if the cached file has been active within a second predetermined period of time at step  86 . If cached file  42 - 1  has been active during the second predetermined period of time, cache manager  16  can promote cached file  42 - 1  to active status. Otherwise, cache manager  16  can continue to poll cached file  42 - 1  according to the second polling frequency. At step  88 , cache manager  16 , can determine if cached file  42 - 1  has been inactive (e.g., has not been accessed or modified), for at least the second predetermined period of time (i.e., can determine if the entire second predetermined period of time has elapsed without activity). If cached file  42 - 1  has not been accessed or modified for at least the second predetermined period of time, cache manager  16  can demote cached file  42 - 1  to non-active status and maintain cached file  42 - 1  as non-active (step  90 ).  
         [0040]    At step  91 , cache manager  16  can determine if cached file  42 - 1  has been active (e.g., can poll according to a third schedule or can receive notification from file management system  35 ) and, if so, can re-promote cached file  16  to active status. Otherwise, at step  92 , cache manager  16  can determine whether cached file  42 - 1  should be removed from cache  18 . This decision can be based on whether the number of non-active cached files has exceeded a certain size or if cached file  42 - 1  has not been accessed for a third predetermined period of time (e.g., cached file  42  has become stale). If at step  92  cache manager  16  determines that cached file  42  should be removed from cache  18 , cache manager  16  can delete cached file  42 - 1  from cache  18  at step  94 .  
         [0041]    It should be noted that prior to deleting cached file  42 - 1 , cache manager  16  can notify the user that cache manager  16  is going to delete cached file  42 - 1 , so that the user has an opportunity to back up cached file  42 - 1 . If, however, at step  92  cache manager  16  determines that cached file  42 - 1  should not be removed from cache  18 , cache manager  16  can maintain cached file  42 - 1  in the non-active list. It should be rioted that the process shown in FIG. 3 refers to a system in which cache manager  16  maintains an active file list, a less active file list, and an inactive file list. However, it should be understood that additional file lists that correspond to polling at different frequencies can be maintained. In summary, cache manager  16  can poll recently active files at a higher frequency and poll less active files at a lower frequency. If during polling it is determined that an active file has not been active for some predetermined period of time, that file can be demoted to less active status. Conversely, if a less active file has been active as determined by polling according to the second polling frequency, that file can be re-promoted to active status. Additionally, if a less active file has not been active for a second predetermined period of time, that less active file can be demoted to non-active status and can eventually be removed from cache  18 . By polling less active files at a lower frequency than more active files, significant system resources can be saved, thereby increasing overall system speed and performance. Additionally, because a cache manager according to the teachings of the present invention does not require detailed contextual information about the files that it is managing, such a cache manager can be easily implemented with any cache.  
         [0042]    Embodiments of the present invention have been described in the context of managing cached files associated with database assets by way of example and the embodiments described are not limiting of the scope of the present invention. Embodiments of the present invention are also applicable to managing cached assets such as files, instructions and so on any system in which a cache is used.  
         [0043]    Although the present invention has been described in detail herein with reference to the illustrative embodiments, it should be understood that the description is by way of example only and is not to be construed in a limiting sense. It is to be further understood, therefore, that numerous changes in the details of the embodiments of this invention and additional embodiments of this invention will be apparent to, and may be made by, persons of ordinary skill in the art having reference to this description. It is contemplated that all such changes and additional embodiments are within the scope of this invention as claimed below.