Abstract:
An improved caching method comprising: (a) employing circuitry to identify and analyze a plurality of data streams, each of said data streams resulting from a request to access a same content item stored in a cache; (b) calculating an initial access interval for said content item based upon said analyzing; and (c) adjusting a data transfer rate in at least one of said data streams in order to reduce said initial access interval to a reduced access interval.

Description:
REFERENCE TO RELATED APPLICATION 
     This application is related to co-pending application by the same inventors as the present application entitled “INTER-NETWORK TRANSLATION; U.S. application Ser. No. 11/482,608; the specification of which is fully incorporated herein by reference. 
     FIELD OF THE INVENTION 
     The present invention relates to cache storage. 
     BACKGROUND OF THE INVENTION 
     It is common practice in computerized networks to store data in a temporary storage location in order to reduce a need to retrieve the same data from a remote location in the future. The temporary storage location is commonly referred to as a cache. In general a cache has a finite size. Therefore, a number of cache management techniques have been developed in an attempt to allocate the limited storage space in the cache among a large number of diverse requests and responses. 
     For example, in a video server environment, some video objects (e.g., movies) are very large and are read sequentially. This makes caching of the entire object inefficient. In caching video movies, a technique called head caching, in which a first portion of each object is stored, is often employed. Implementation of head caching means that a first portion of a video object is retained in a local cache. A request for the object results in streaming of data from the local cache to the requesting device with concurrent retrieval of the remainder of the object from its remote source. 
     An additional caching algorithm, referred to as interval caching, is employed to handle concurrent requests from similar devices for a same content resource. In interval caching, the sequential relationship of data blocks is exploited and the interval defined by multiple successive streams of the same content is cached (“A Generalized Interval Caching Policy for Mixed Interactive”, A. Dan, D. Sitaram (1996) http://citeseer.ist.psu.edu/cachedpage/164940/1; the disclosure of which is fully incorporated herein by reference). The set of data blocks between a first and last block currently being accessed by one of the streams is termed the “access interval”. 
     In cases where requests for the same content are received over a period of time, “ . . . it is preferable to retain the cached content over a relatively long time period.” (Proxy Caching for Media Streaming Over the Internet”—a survey, J. Liu, J. Xu, http://www.cs.sfu.ca/˜jcliu/Papers/comm04.pdf; the disclosure of which is fully incorporated herein by reference). However, the effectiveness of Interval Caching “ . . . diminishes with increased access intervals. If the access interval of the same object is longer than the duration of the playback, the algorithm is degenerated to the unaffordable full-object caching.” (J. Liu, J. Xu; Ibid.). For software updates to multiple devices of the same type which are served new software from a central site, this becomes a significant problem as software upgrade operations are not executed at the same precise time. 
     In general, the more content retained in a cache, the greater the memory requirements of the cache. However, since a single cache is often employed for more than one file and/or object and/or task, decreasing storage time can compensate to some degree for decreasing storage volume in reducing a required cache size. 
     Attempts to optimize the use of cache resources can result in increased complexity of the caching algorithm (see for example “Resource Based Caching for Web Servers” http://www.cs.utexas.edu/users/vin/pub/pdf/mmcn98rbc.pdf; the disclosure of which is fully incorporated herein by reference) 
     U.S. Pat. No. 5,787,472 relates to a disk caching system for selectively providing interval caching or segment caching of video data. The specification of this patent is fully incorporated herein by reference. 
     U.S. Pat. Nos. 6,834,329; 6,754,699 and 6,742,019 relate to caching technology and are cited here as being indicative of the general level of the art. The specifications of these patents are fully incorporated herein by reference. 
     SUMMARY OF THE INVENTION 
     An aspect of some embodiments of the present invention relates to reducing an access interval for a content item being downloaded from a network cache in multiple data streams. In an exemplary embodiment of the invention, reducing the access interval is achieved by implementing flow control. Optionally, flow control includes differential allocation of bandwidth among network devices. Optionally, differential allocation of bandwidth is achieved by imposing pauses between receipt of an acknowledgement for a previous data block and a beginning of transmission of a next data block. In an exemplary embodiment of the invention, the pauses do not cause the request to time out. In an exemplary embodiment of the invention, flow control reduces a required size of a cache. Optionally, this cache size reduction contributes to a cost savings in network operation. Optionally, the savings result from making the cache resources available for other tasks. 
     Optionally, each data stream is directed towards a similar network device which issued a request for the content item. Optionally, the content item is a software upgrade. Optionally, the network devices are IP telephones (optionally wireless) and/or wireless access points. In an exemplary embodiment of the invention, a plurality of similar network devices request and receive a software upgrade concurrently. 
     In an exemplary embodiment of the invention, flow control is implemented unequally among the multiple data streams. In an exemplary embodiment of the invention, the degree of flow control with respect to a specific data stream changes over time. Optionally, flow control is implemented automatically. 
     In an exemplary embodiment of the invention, an initial request for all data packets belonging to a content item residing outside a local area network is made by a device residing inside the local area network. The initial request is cancelled when only a subset of the data packets are received. This is followed by at least one supplementary request for at least a portion of the un-received data packets. This requesting/canceling/supplementary requesting shifts a data storage burden away from the cache to a remote server. Optionally, the remote server supplies the subsequent packet when a previous packet is to be deleted from the cache. Optionally, the subsequent request is made after at least a portion of the received data packets have been cleared from the cache. Optionally, the content item is larger than the available cache. 
     Optionally, the previous packet is deleted from the cache after distribution to a plurality of devices within the network. Optionally deletion is based upon a deletion priority which considers access interval analysis. Optionally packets are further divided to facilitate distribution. In an exemplary embodiment of the invention, this distribution permits an interface between a WAN protocol (e.g. HTTP) and a LAN protocol (e.g. TFTP). Optionally, packets are transferred to devices using TFTP. 
     Optionally, the cached packet is one of a plurality of packets belonging to a resource being concurrently distributed to multiple devices. Optionally, the resource is a software resource, for example a software update. 
     In an exemplary embodiment of the invention, devices which begin retrieval of a specific packet from the cache at an earlier time are allocated less bandwidth than other devices which begin retrieval of the same specific packet from the cache at a later time. Optionally, multiple devices of the same type finish retrieval of a same cached packet served from a central site in synchrony. 
     In an exemplary embodiment of the invention, each packet is cached only one time. Optionally, multiple devices participating in the distribution receive the packet within 30 seconds, optionally within 5 seconds, optionally within 1 second or lesser or greater or intermediate times. 
     In an exemplary embodiment of the invention, there is provided an improved caching method, the method comprising: 
     (a) employing circuitry to identify and analyze a plurality of data streams, each of said data streams resulting from a request to access a same content item stored in a cache; 
     (b) calculating an initial access interval for said content item based upon said analyzing; and 
     (c) adjusting a data transfer rate in at least one of said data streams in order to reduce said initial access interval to a reduced access interval. 
     Optionally, said cache is a local network cache. 
     Optionally, said request is a TFTP request. 
     Optionally, said adjusting is accomplished by differentially allocating available bandwidth among said data streams. 
     Optionally, said differentially allocating available bandwidth among said data streams includes introducing a pause into at least one stream selected from said streams. 
     Optionally, a total amount of memory allocated to said cache depends at least partly upon a size of said access interval. 
     Optionally, said content item comprises a plurality of data blocks. 
     Optionally, said reducing said access interval reduces a size of a portion of said cache allocated to said content item. 
     Optionally, the method includes dividing said content item into blocks. 
     In an exemplary embodiment of the invention, there is provided a method for distributing a content resource to a plurality of devices installed within a network, the method comprising: 
     (a) employing circuitry to determine a predicted interval of time between completion of distribution of a defined portion of a same content resource residing in a cache to a device belonging of a plurality of devices and at least one additional device of the plurality of devices;
 
(b) altering a distribution schedule of said defined portion of a content resource among said devices in said plurality of devices so that said predicted interval is reduced.
 
     Optionally, said cache is a local network cache. 
     Optionally, said reducing said interval of time is achieved by differential allocation of available bandwidth among devices belonging to said plurality of devices. 
     Optionally, said defined portion of the content resource is cached only one time and is distributed to the plurality of devices 
     Optionally, said defined portions are packets. 
     Optionally, said defined portions are blocks. 
     Optionally, the content resource is a software resource. 
     Optionally, said distribution of blocks is according to TFTP. 
     Optionally, said defined portion of the content resource is removed from said cache after distribution thereof to the plurality of devices is complete. 
     Optionally, said specific packet resides in said cache for 30 seconds or less. 
     Optionally, said specific packet resides in said cache for 5 seconds or less. 
     Optionally, said specific packet resides in said cache for 1 second or less. 
     In an exemplary embodiment of the invention, there is provided a network caching method, the method comprising: 
     (a) providing a cache containing at least a portion of a software upgrade; 
     (b) employing circuitry to ascertain a number of current requests for said software upgrade by a plurality of similar communication devices and a relative progress of each of said requests; 
     (c) differentially allocating a bandwidth resource among said communication devices so that said relative progress of each of said requests becomes more similar. 
     Optionally, said cache is a local network cache. 
     Optionally, said requests are TFTP requests. 
     Optionally, said cache employs an access interval algorithm and said differentially allocating said bandwidth resource reduces said access interval. 
     Optionally, said similar communication devices include IP telephones. 
     Optionally, said similar communication devices include wireless access points. 
     Optionally, the method includes adjusting said differentially allocating over time. 
     In an exemplary embodiment of the invention, there is provided an improved caching method, the method comprising employing circuitry to: 
     (a) ascertain an initial access interval for a content item; and 
     (b) reduce said initial access interval to a reduced access interval. 
    
    
     
       BRIEF DESCRIPTION OF DRAWINGS 
       In the Figs., identical structures, elements or parts that appear in more than one Fig. are generally labeled with the same or similar numeral in all the Figs. in which they appear. Dimensions of components and features shown in the Figs. are chosen for convenience and clarity of presentation and are not necessarily shown to scale. The Figs. are listed below. 
         FIG. 1  illustrates alternate installation configurations for a computerized gating device facilitating content transfer between prior art LAN devices and a prior art WAN server according to some exemplary embodiments of the present invention; 
         FIG. 2  schematically illustrates functional components of a gating device according to an embodiment of the present invention in greater detail; 
         FIG. 3  schematically illustrates a caching module of a gating device according to an embodiment of the present invention in greater detail; 
         FIGS. 4A and 4B  illustrate access intervals near the beginning of a coordinated software upgrade and at a later stage of the process according to an embodiment of the present invention; and 
         FIG. 5  is a diagram illustrating how dynamic flow control according to some embodiments of the invention reduces an access interval. 
     
    
    
     DETAILED DESCRIPTION OF EMBODIMENTS 
     General System Architecture 
     In order to make the significant advantages of the present invention more clear, a brief explanation of prior art LAN networks and their interaction with a prior art remote server located across a WAN, such as the Internet is presented. 
       FIG. 1  illustrates exemplary system architecture  100  facilitating communication between WAN server  110  and client LANs  170 B and  170 C. Server  110  typically employs a WAN transfer application layer protocol such as, for example, HTTP, HTTPS, SCP, SFTP or FTP (indicated by arrow  180 ). Previously available alternatives generally presumed that devices residing in LANs  170 B and/or  170 C would communicate with server  110  according in order to access content in either a high parallelity protocol such as HTTP, HTTPS, FTP, SFTP or SCP or in a low parallelity protocol such as TFTP. As a result, devices in LANS  170 B and/or  170 C which communicated in low parallelity protocols such as TFTP derived little benefit from remote content such as that stored on WAN server  110 . 
     This is because high parallelity protocols operate with reasonable efficiency across a WAN link and transfer of a requested content resource is generally successful. Most personal computers in use today employ a high parallelity protocol such as HTTP to retrieve content from remote servers. 
     In contrast, low parallelity protocols are inefficient over WAN links and are prone to timeouts and/or repeat requests. As a result, use of low parallelity protocols over a WAN link is undesirable both from the standpoint of a requesting device  150  and from the standpoint of bandwidth utilization in a WAN link  130 . 
     “Parallelity” as used herein, refers to a number of data transfer units (e.g., packets) concurrently sent by a responding device in response to a single acknowledgment. As the parallelity of a protocol increases, the number of requests and responses that can be pipelined on a single TCP connection also increases. Pipelining allows transmission of additional data packets without waiting for a response to a previous data packet. Pipelining allows a single TCP connection to be used more efficiently, with reduced elapsed time for completion of a task. 
     Some endpoint devices  150  (e.g. wireless access points  150 A and  15 B and/or IP phones  150 C;  150 D;  150 E;  150 F;  150 G and  150 H) are configured with limited communication capabilities and are capable of communicating only in low parallelity protocols (e.g. TFTP; indicated by arrow  182 ). The term telephone as used in this specification and the accompanying claims includes IP telephones as well as telephones which operate through the public switched telephone network as well as wireless phones and/or wireless access points. In an exemplary embodiment of the invention, analog phones with a modem capability and IP stack access a TFTP server over PSTN. These devices with limited communication capabilities typically derived little benefit from content items stored outside their own LAN. In cases where devices with limited communication capabilities attempted to retrieve content items stored outside their own LAN their requests often timed out. Repeated unsuccessful attempts to complete a download of a content item from remote server  110  made unnecessary demands on WAN links  130 . 
     In order to circumvent the problem of repeated unsuccessful attempts to complete a download of a content item from remote server  110  and/or unnecessary demands on WAN links  130  it was common to install a TFTP server (not shown) within each LAN for distribution of content to limited capability devices  150 . The TFTP server required advance installation of appropriate content items for the limited capability devices  150 . The advance installation typically required human intervention and is commonly referred to as manual provisioning. 
     Manual provisioning was used, for example, in cases where a local TFTP server was installed in each branch (e.g. branch X [ 170 C] and branch Y [ 170 B]) to solve the problems of using WAN connection for upgrade from central office  170  by large numbers (e.g. thousands) of IP phones  150 . 
     Before explaining functional details of the invention in detail, reference is again made to  FIG. 1  which illustrates some possible placements of a gateway/translator  200  according to embodiments of the invention (marked  200 B and  200 C) so that it may facilitate communication between a WAN server  110  and a plurality of endpoint devices  150  (marked  150 A- 150 H). Endpoint devices  150  may include substantially any communication device including, but not limited to telephones (e.g. IP phones), wireless access points, computers, embedded processors, pagers and satellite location determination units. In the pictured embodiment, endpoint devices  150  include wireless access points ( 150 A and  150 B) and IP telephones ( 150 C;  150 D;  150 E;  150 F;  150 G and  150 H). Additional examples of endpoint devices (not pictured) are wireless IP phones connected via a wireless link to wireless access points (e.g.  150 A and/or  150 B). 
     In an exemplary embodiment of the invention, endpoint devices  150  are characterized by limited memory and/or processing power, and therefore employ a simple protocol such as TFTP. In some embodiments of the invention, endpoint devices  150  have less than 8 Mb, optionally less than 1 Mb of available RAM memory or even less that 300 Kb of available memory. 
     For example, a TFTP Server/Client operating in VxWorks OS may require about 15 Kbytes of RAM to perform an update. An HTTP Server and Client operating in Linux OS may require 90-150 KBytes to perform a similar task. Optionally, HTTP require at least 3 times as much available Ram memory as TFTP. In many cases, this difference is reflected in R&amp;D effort and time to develop HTTP Client/Server in comparison to TFTP Client/Server. 
     Deployment of a Gateway/Translator Within the Network Architecture 
     In an exemplary embodiment of the invention, WAN server  110  resides in a LAN  170 A and is connected externally through a router  120 A. WAN server  110  is optionally capable of receiving requests and sending responses across an Internet  140  via WAN links  130  across Internet  140 . Requests optionally originate from, and return to, other LANs (e.g.  170 B and  170 C). Optionally, LAN  170 B includes a router  120 B in addition to a gateway/translator  200 B according to the present invention. In LAN  170 C, gateway translator  200 C according to the present invention communicates directly with WAN server  110  via a WAN link  130  and optionally performs the function of a router. 
     Typically, WAN links  130  between server  110  and LANs  170 C and/or  170 B are characterized by a long round trip delay, above 50 milliseconds, or even 200 milliseconds, In some embodiments of the invention, in order to overcome long round trip delay, a protocol which allows transmission of a plurality of packets before acknowledgments are received, is used to control the communications between server  110  and gateway  200 . Optionally, the transmission protocol comprises a sliding window protocol, for example TCP/IP. TCP employs a window which allows it to send packets before receipt of acknowledgements. The window is part of the TCP connection characteristics and HTTP takes advantages of the TCP window. TCP allows HTTP applications to send a next packet before getting acknowledgements to a previous packet. As an example, a TCP default window size is up to 64 KB. Optionally, this window is scalable to 1 GB as part of the TCP establishment session protocol. 
     In an exemplary embodiment of the invention, Windows 2000 allows 16K windows size rounded up to twelve 1460-byte segments over Ethernet interface. In an exemplary embodiment of the invention, Windows NT allows 8760 windows size rounded up to six 1460-byte segments over Ethernet interface. 
     However, network devices configured to operate in /UDP/IP are incapable of such transmission. As a result, they derive no benefit from the relatively high parallelity of the TCP/IP environment in the LAN. Theoretically it is possible to implement a layer over UDP/IP that simulates the TCP/IP layer and create efficient/high speed transfer protocol, but this is contrary to the generally accepted layer model. 
     In an exemplary embodiment of the invention, gateway/translators  200 B,  200 C are provided to allow a device or group of devices  150  residing in a LAN (e.g.  170 C or  170 B) to access content from WAN server  110 . In an exemplary embodiment of the invention, the content may be software for installation and/or upgrade. In an exemplary embodiment of the invention, access includes translation and/or conversion of requests originating from devices  150  and/or responses supplied by server  110 . In an exemplary embodiment of the invention translation and/or conversion includes translation between protocols with different degrees of parallelity (e.g. TCP/IP and UDP/IP) and/or conversion of data transfer units of a first size to data transfer units of a second size. In an exemplary embodiment of the invention, the gateway also includes a local network cache so that some requests may be processed locally, without being relayed to remote server  110 . Optionally, this local processing of requests by the network cache reduces a burden on available bandwidth between LANs  170 B and  170 C and server  110 . In an exemplary embodiment of the invention, a device in a UDP/IP LAN environment issues a TFTP request which is intercepted and translated into a HTTP/TCP/IP request. The request elicits an HTTP response which is translated into a series of TFTP/UDP/IP data blocks and relayed to the requesting device. Optionally, this reduces the need for sending a low parallelity request across a WAN link. Optionally, this reduces the need for manual provisioning of a local server. 
     Gateway  200  according to some embodiments of the invention may be deployed, for example in remote branch offices of a company with headquarters housing server  110 . By deploying a gateway  200  in this way, a company might distribute software updates from server  110  located at headquarters  170 A to branches  170 B and  170 C where devices  150 A- 150 H such as IP phones and/or wireless access points are located. Alternatively or additionally, server  110  belongs to a service provider which services a plurality of companies not associated with the company operating the branch offices. This configuration reduces the need for devices  150  to attempt communication with server  110  in an inefficient low parallelity protocol and/or reduces the need for manual provisioning of a local server in LAN  10 B and/or  170 C. 
     Throughout the text and figures, any device, server or component thereof described/depicted as a single unit may reside is two or more separate physical entities which act in concert to perform the described/depicted function. Alternatively or additionally, any device, server or component thereof described/depicted as two or more separate physical entities may be integrated into a single physical entity to perform the described/depicted function. 
     Gateway Overview 
       FIG. 2  is a block diagram of Gateway  200  and its connections within network architecture  100 , in accordance with an exemplary embodiment of the invention. Gateway  200  optionally comprises an Endpoints Protocol Adapter (EPA;  240 ), a Content Cache Manager (CCM;  300 ) and a Server Protocol Adapter (SPA;  220 ). In an exemplary embodiment of the invention, gateway  200  processes one or more of outgoing requests from devices  150 A- 150 H and incoming responses from server  110 . 
     Handling of Outbound Requests 
     In an exemplary embodiment of the invention, gateway  200  intercepts any outbound request originating from a device  150  and formatted according to a low parallelity and/or insecure protocol, such as TFTP. Optionally, gateway  200  evaluates the request and determines that it is either a “new request” or a “repeat request”. 
     For purposes of this specification, a “new request” refers to a request for a content item /WAN server  110  combination which does not match an earlier request and/or cannot be filled with a stored or cached response from an earlier request. A content item may be, for example, a file or a portion of a file stored on server  110 . Optionally, a new request is determined according to filename. Optionally, internal management of the file/blocks in the gateway relies upon one or more of Client IP address, Client Port and Server Port. 
     For purposes of this specification, a “repeat request” refers to a request for a same content item on a same WAN server  110  as designated in an earlier request. 
     According to various embodiments of the invention, “an earlier request” may refer to an earlier request from a different device  150 , and/or a request currently being handled by gateway  200  and/or a request for which an appropriate response is currently residing in a local network cache or local network storage. 
     In an exemplary embodiment of the invention, new requests are concurrently stored locally by gateway  200  and relayed to WAN server  110  so that server  110  will provide the requested content item as a response. In an exemplary embodiment of the invention, repeat requests are stored by gateway  200  and matched with an appropriate response from an earlier new request. Optionally, the appropriate response is already available, for example in a network cache operated by gateway  200 . Optionally, the appropriate response has not yet been received from server  110 . 
     Handling a New Outbound Request 
     For purposes of illustration, a request originating from IP phone  150 F in LAN  170 C is described in detail. In this illustrative example, gateway  200 C of LAN  170 C communicates with devices  150  using TFTP and the request originates from device  150 F as a TFTP request. TFTP operates in a UDP/IP environment which requires an acknowledgement for each transmitted data transfer unit. WAN server  110  will be described, for purposes of illustration as an HTTP server which operates primarily in TCP/IP. HTTP/TCP permits concurrent transmission of as many as 44 data packets in response to a single request prior to receipt of an acknowledgement. 44 data packets is an example based upon a window of 64 KB and 1518B Ethernet packet length. The window can be changed to be smaller or larger according to the negotiation results between the endpoints. Thus, the actual number of data packets may be higher or lower than 44. It is stressed that TFTP and HTTP are used as examples only and that any low parallelity and/or insecure protocol could be substituted for TFTP and any high parallelity and/or secure protocol could be substituted for HTTP. Examples of high parallelity TCP/IP protocols include, but are not limited to HTTP and FTP. Secure versions of these protocols, HTTPs and FTPS are also available. 
     In the example, the request is from device  150 F in the form of an IP phone. The request for a content item stored on server  110  is intercepted by gateway  200 . Interception may be, for example, by endpoints protocol adapter (EPA)  240  as illustrated in  FIG. 2 . In an exemplary embodiment of the invention, EPA  240  relays the request to content cache manager (CCM)  300 . In some embodiments of the invention, CCM  300  determines if the request matches a similar request previously handled by CCM  300 . The request is for a specified content item stored on server  110 . According to the example, the request is in TFTP format. In the current example, CCM  300  compares the request to other requests it is currently handling and determines that it is a new request. The request is therefore concurrently stored and relayed to server protocol adapter  220 . Storage of the outbound request may be, for example, in EPA  240  or CCM  300 . 
     SPA  220  translates the request into a suitable high parallelity and/or secure protocol, HTTP in this example. This translation may involve reorganization of the request from one or more TFTP blocks into one, or optionally more than one, HTTP packets. Optionally, the request includes an address of WAN server  110  when it originates from device  150 . Alternatively, gateway  200  adds the address of WAN server  110  to the request. In an exemplary embodiment of the invention, translation of the outgoing request includes substituting a return address corresponding to device  150  with a return address corresponding to gateway  200  so that the outgoing HTTP request produces a response from server  110  addressed to gateway  200 . Optionally, CCM  300  compiles a list of addresses for all devices  150  issuing requests for the same content item/server  110  pair. In an exemplary embodiment of the invention, CCM  300  employs the list compiled by CCM  300  to determine which devices  150  will receive a same response. 
     Handling of the HTTP request from the time it leaves SPA  220  is according to HTTP convention. In some embodiments of the invention, the HTTP request transmitted by SPA  220  is such that server  110  can not differentiate between a request that originated as a TFTP request in LAN  170  and a request originating from an HTTP device such as a PC operating a WWW browser. 
     In response to the request, server  110  prepares an HTTP response which may include one or more packets of information. These are sent on a return path according to the return address indicated in the request (e.g. device  150  and/or gateway  200 ). A separate section hereinbelow describes “Handling of incoming responses” by gateway  200 . 
     Handling a Repeat Outbound Request 
     For purposes of illustration, an additional request originating from IP phone  150 G in LAN  170 C is described in detail. In this second example, the request from device  150  G arrives at EPA  240  of gateway  200  after the request originating from device  150  F has been received. 
     As in the above example, EPA  240  relays the request to CCM  300 . In this second example, CCM  300  determines that the content item/server  110  specified in the request match those of the previous request from device  150 F. CCM  300  therefore identifies the request from device  150 G as a “repeat request”. The exemplary repeat request of device  150  G is stored by gateway  200 , for example, in EPA  240  or CCM  300  but is not translated to HTTP by SPA  220  or relayed to server  110 . 
     Each repeat request is matched with an appropriate response from an earlier new request. Depending upon the time delay between the original new request and the repeat request, the appropriate response may either already be available (e.g. in a network cache) or may not yet have been received from server  110 . If the appropriate response is not yet available, gateway  200  stores the request until such time as an appropriate response is available. 
     Handling of Incoming Responses 
     Discussion of incoming responses is in the context of the two illustrative examples presented hereinabove and should not be construed as limiting the invention. 
     Each new request relayed to server  110  will elicit an HTTP response in the form of one or more HTTP packets. The HTTP response arrives at gateway  200  and is processed by SPA  220 . In this illustrative example the response to the new request issued by device  150 F is translated from HTTP to TFTP by SPA  220 . SPA  220  relays the incoming response to CCM  300 . 
     The HTTP response is generally received in packets of a size determined by the maximum transfer unit (MTU) of the network path between server  110  and gateway  200 . 
     The MTU is set by the Layer 2 interface (e.g. Ethernet, or Serial interface as frame relay or PPP) and it not part of the TCP/IP and UDP/IP stack. This feature of the Layer 2 interface optionally compensates for the inability of the HTTP protocol to set up block size. Exemplary packet sizes commonly used in the art are 576 bytes and 1536 bytes but the present invention is not limited to any specific packet sizes. TFTP has extension/TFTP option to support other then 512B block sizes. 
     The translation optionally includes division of one or more packets of the HTTP response from server  110 , into blocks of a size suitable for the TFTP environment of LAN  170 . In an exemplary embodiment of the invention, SPA  220  divides the response into TFTP blocks, for example blocks of 512 bytes. In an exemplary embodiment of the invention, a one or more large packets are divided into a plurality of smaller blocks and each block is stored. 
     In an exemplary embodiment of the invention, the MSS option of TCP is employed to set a maximum segment size (MSS) as part of the establishment of a TCP connection for use used during the duration of the TCP connection. Optionally, MSS is employed to synchronize HTTP (TCP) and TFTP block sizes. This option can reduce the need for division of incoming response packets at gateway  200 . 
     Optionally, each TFTP block is stored until acknowledgment is received that the block has been delivered to the device  150  which made the request that resulted in delivery of the HTTP packet containing the block. 
     In an exemplary embodiment of the invention, gateway  200  stipulates an MSS of 512 bytes in each request relayed to server  110 . This stipulation results in an incoming response with each HTTP packet sized to correspond to a single TFTP block. MSS specification may, for example, reduce a workload of gateway  200 . 
     Optionally, each TFTP block is stored until acknowledgment is received that the block has been delivered to the device  150  which made the request that resulted in delivery of the HTTP packet containing the block. 
     In an exemplary embodiment of the invention, each block is cached even after it was delivered to the device  150  for which it was fetched from server  110 , in case other devices  150  request the same or similar data. Alternatively or additionally, a block may be deleted from storage and/or cache before it has been delivered to all relevant devices  150  and be re-requested from server  110  to supply to one or more devices  150 . Gateway  200  may optionally perform this deletion and re-requesting in order to temporarily provide space in a cache. 
       FIG. 3  is a schematic representation of functional components of a content cache manager (CCM)  300 , in accordance with an exemplary embodiment of the invention. While the exact architecture of CCM  300  may vary, it is depicted as including an interface controller  320 , a cache controller  340  and a storage  360 . As indicated in  FIG. 3 , interface controller  320  of CCM  300  serves as a gate between server interface  220  and endpoint interface  240 . In an exemplary embodiment of the invention, CCM  300  matches between outgoing TFTP requests and incoming HTTP responses. In an exemplary embodiment of the invention, CCM  300  stores requests in storage  360  until an appropriate response is identified and relayed to device  150 . Optionally, CCM  300  matches requests and responses using data pertaining to server  110  and/or a requested content item. 
     In an exemplary embodiment of the invention, CCM  300  match requests and responses by identifying a server/content item combination. For example, a new request relayed to server  110  may specify a destination address of 255.244.164.0 and a content item of Communicall V2.7.1.ZIP. CCM  300  optionally logs and stores series of subsequent requests with a similar address and content item designation. When a response indicating 255.244.164.0 as the sending device and Communicall V2.7.1.ZIP as the file name is received, CCM  300  matches this response to the request originally relayed to server  110  and all members of the series of subsequent requests with a similar address and content item designation. 
     Initiating Concurrent Requests 
     In an exemplary embodiment of the invention, a group of devices  150  are induced to make a similar request concurrently. The request may be, for example, a request for a software installation/upgrade download. 
     In some embodiments of the invention, a central server issues a command to all devices of type X to request software version Y. The server may be, for example a controller located in the same LAN as the devices of type X. In an exemplary embodiment of the invention, gateway  200  issues the command. In an exemplary embodiment of the invention, the controller issues the command to all devices of type X concurrently, optionally simultaneously. In an exemplary embodiment of the invention, the controller issues the command to devices of type X in sequential groups, with all devices in each group receiving the command concurrently, optionally simultaneously. In an exemplary embodiment of the invention, the controller issues the command to each device of type X sequentially. Sequential issue of a command to multiple devices may be with random and/or defined intervals between commands. Optionally, sequential issue of commands prevents an overload on gateway  200  by preventing multiple similar requests from devices  150  being received simultaneously. 
     In some embodiments of the invention, each device  150  makes a request for upgrade. Optionally, devices  150  are programmed to check for available software upgrades during start up. This “check during start-up” feature permits a system administrator to initiate a software upgrade by, for example, turning off all of devices  150  and turning them back on. Optionally, power to devices  150  is provided from a central location, such as a computerized controller, a common electric circuit or a single electric junction box. Providing power to devices  150  from a central location facilitates coordinated shut down and restart by shutting off the power and turning it back on. 
     Coordinated shut down and restart may be achieved electronically (if a computerized controller controls the circuits) or manually (if the circuits are controlled by one or more switches in a junction box). 
     In an exemplary embodiment of the invention, coordinated restart causes all of devices  150  to begin a start up routine within a short interval of time, for example within 30 seconds. 
     In an exemplary embodiment of the invention, devices  150  are IP phones which, as part of their startup routine, load a current software version, perform a DHCP process to get an IP address and then begin a TFTP process to check with WAN server  110  whether there is a need to update software. As a result, the number of checks for software updates corresponds to the number of devices  150  on the circuit. 
     In an exemplary embodiment of the invention, the controller may receive a prompt which causes the controller to urge devices  150  to request a software update. For example, server  110  may send a message to the controller including the information: 
     “Communicall V2.7.1. now available; replace earlier versions” 
     The controller responds by sending the following commands to devices  150 ; 
     “Check if Communicall software installed; if no, take no action, if yes check version number; 
     If version number is less than 2.7.1, shutdown and restart.” 
     Although only four devices  150  are pictured in each of LANS  170 , the invention will work with any number of devices  150 . Some typical networks include hundreds or even thousands of devices. In an exemplary embodiment of the invention, as the number of similar devices  150  increases, the percentage of requests for software upgrade relayed outside the LAN to server  110  decreases. Optionally, processing requests without relaying them to a remote server increases available Internet bandwidth for other functions and/or reduces dependence on manual provisioning and/or providing/managing local TFTP servers. 
     In an exemplary embodiment of the invention, gateway  200  reduces the average time required for each of devices  150  to complete a software upgrade. Gateway  200  may optionally achieve this reduction in time by causing requests received in a low parallelity protocol to be handled in a high parallelity protocol over most of their path. Alternatively or additionally, gateway  200  achieves this reduction by implementation of a network cache as described in greater detail hereinbelow. In an exemplary embodiment of the invention, gateway  200  reduces the need for manual provisioning of a local server by facilitating efficient direct communication between devices  150  and remote server  110 . 
     In an exemplary embodiment of the invention, gateway  200  is concerned only with requests and responses and does not attempt to ascertain what devices  150  do with a response after it has been provided to them. Optionally, initiation of concurrent requests is performed for devices  150  which are similar, but not necessarily identical, and issue identical requests. In some cases, an identical installation is performed on all devices  150  issuing the identical requests. In other cases slight differences dictated by variations in hardware configuration of devices  150  cause individual devices to perform slightly different upgrades or installations. These differences in hardware configuration may result, for example, from installation of devices of different models from a single manufacturer in a single LAN  170 . 
     In an exemplary embodiment of the invention, gateway  200  is installed in a LAN including a group of devices  150  with different versions of software installed (e.g. versions 1.0; 1.01; 1.1; 1.2 and 1.21). In an exemplary embodiment of the invention, all conform to a single version (e.g. version 2.5) after upgrade. Again gateway  200  is concerned only with requests and responses and does not attempt to ascertain what devices  150  do with a response after it has been provided to them so that each device  150  may be sequentially upgraded through a series of intervening versions until the most recent version (e.g. version 2.5) is achieved. In an exemplary embodiment of the invention, LAN  170 A represents a corporate headquarters and LANS  170 B and  170 C represent corporate branch offices. 
     Implementation of a Network Cache 
     In general, a network cache is implemented to reduce the need for communication outside the LAN. When managing a network cache the total available storage space in the cache must be balanced against the storage requirements imposed on the cache by various tasks it must perform. Different cache management algorithms have been implemented in the past for various types of tasks. 
     In an exemplary embodiment of the invention, the cache is designed and configured to handle a large number of similar requests received from similar devices  150  in a short period of time. Optionally, the cache concurrently stores other items related to other tasks. As explained above, only one of the large number of similar requests is defined as a “new” request and relayed to server  110 . The remaining requests are defined as repeat requests and handled within the LAN by gateway  200 . 
     For purposes of illustration, it is convenient to discuss CCM  300  in terms of three functions; interface controller  320 , cache control  340  and storage  360 . While these functional modules are depicted as physically separate entities in  FIG. 3  for clarity, they may reside together in a single hardware item in practice. 
     Interface controller  320  serves as a bridge between EPA  240  and SPA  220 . Traffic across the bridge is optionally bidirectional. 
     With respect to traffic originating in the LAN  170 , interface controller  320  optionally evaluates outbound requests in a LAN format (e.g. TFTP) and determines if each request is a “new” or a “repeat” request as defined hereinabove. Interface controller  320  will route both “new” and “repeat” requests to storage  360  (optionally through cache control  340 ) but only new requests will be relayed by interface controller  320  to SPA  220  for translation to a WAN format, such as HTTP. 
     With respect to traffic originating outside the LAN, interface controller  320  optionally receives responses from server  110  and routes them to cache control  340 . Optionally, the responses are translated from a WAN format (e.g. HTTP) to a LAN format (e.g. TFTP) by SPA  220  before they arrive at Interface controller  320 . In the context of the illustrative examples set forth above, responses will be divided into a plurality of TFTP blocks, each block having a sequential number out of a total number and a designation corresponding to the “new” request which was relayed to server  110 . 
     Each response is relayed to storage  360 , optionally through cache control  340 . Optionally, an incoming HTTP packet of a response is translated into data blocks as described hereinabove. The blocks may be transferred to storage  360  sequentially, or in groups. 
     Cache control  340  matches stored requests with stored responses and sends relevant data blocks to devices  150  in order to fill requests. In an exemplary embodiment of the invention, cache control  340  manages storage  360  so that a large number of requests may be handled using a small amount of storage space in storage  360 . 
     Cache control  340  must consider the total capacity of storage  360  and manage the stored requests and blocks of response so that the capacity of storage  360  is not exceeded. In order to effectively manage storage  360 , cache control  340  may implement one or more known caching algorithms. Known caching algorithms include, but are not limited to head caching, just in time retrieval, least recently used (LRU) and most frequently used (MFU). Because the capacity of storage  360  is finite, cache control  340  may need to delete some items from storage  360 , even if those items may be required again in the future. The requirement to delete may become more stringent when the number of concurrent different tasks increases and/or when the number of requests being handled concurrently increases. 
     In an exemplary embodiment of the invention, cache control  340  allocates a specified volume of memory to a specific content item. The specified volume may optionally be smaller than the size of the content item. Optionally, limiting the volume of memory allocated to a specific content item causes a supplementary request to be issued for an additional portion of the content item once a previous portion has been deleted from storage  360 . In an exemplary embodiment of the invention, the specified volume is defined as a relative amount of a size of the content item and/or a relative amount of the capacity of storage  360 . Optionally, storage  360  may be dedicated in its entirety to a single content item. 
     Interval Caching 
     In an exemplary embodiment of the invention, cache control  340  manages storage  360  using an interval caching algorithm. In interval caching, cache control  360  determines which blocks belonging to a particular response are currently being transferred to at least one device  150 . The blocks of a single response are sequentially ordered, and each response contains a finite number of blocks. According to interval caching, when a large number of similar requests are being concurrently filled from a single cached response, those blocks between the lowest number block and the highest number block currently being relayed to devices  150  determine an access interval. The access interval may be defined as a number of blocks. Blocks in the access interval receive the highest priority to remain in the cache. Because the size of the access interval constitutes a demand on available space in the storage  360 , it is desirable to decrease the size of the access interval. One way to reduce the access interval is to temporally coordinate performance of a similar task by a number of devices  150  as described above in “Initiating concurrent requests”. However, the degree of coordination achieved by temporal coordination of initiation may be insufficient in some cases. 
     Reducing the Access Interval 
     Reduction in the size of the access interval can make additional space available in storage  360  by reducing the number of data blocks which must be concurrently stored. This reduction may be important, for example, when storage  360  is nearly full and/or when storage space for data in an access interval of a current response is greater than a predetermined value. 
     In order to reduce the access interval, the flow of data to different devices  150  concurrently receiving a single response may be dynamically regulated. Dynamic regulation of flow may be achieved, for example, by differential allocation of LAN bandwidth among a plurality of devices  150 . 
     Optionally, cache control  340  differentially allocates bandwidth by increasing and/or reducing a data transfer rate to specific devices  150 . In an exemplary embodiment of the invention, cache control  340  assigns all devices  150  requesting a same content item an arbitrary bandwidth. The arbitrary bandwidth may be a predetermined value (e.g. 4 kbytes/s) or a rule based value. (e.g. 15% of available total bandwidth/[number of requesting devices]). Cache control  340  is then able to increase or decrease the flow rate in a particular data stream by adjusting the bandwidth allocation for the device  150  to which the data stream is directed. 
     In an exemplary embodiment of the invention, cache control  340  differentially allocates bandwidth by introducing short pauses in data transmission to specific devices  150 . Introduction of pauses serves to reduce an average data transfer rate over time. Pauses may be introduced, for example, between data blocks. 
     By way of illustration, in TFTP, an acknowledgement is sent from each device  150  to EPA  240  at the end of each data block. In an exemplary embodiment of the invention, cache control  340  compares the block number of each TFTP acknowledgement to the block number currently being transmitted to other devices  150 . Devices  150  which are receiving a comparatively high block number become candidates for reduced bandwidth allocation, for example in the form of a brief pause before delivery of the next data block begins. This reduced allocation of bandwidth causes those devices which are closest to completing receipt of a specific response from WAN server  110  to wait so that other devices  150  can catch up. The access interval becomes narrower as a result of the imposed pauses. 
     However, if pauses in data transmission are too long, device  150  may perceive the response as being aborted and repeat the request. Repeat requests for the same content item by a single device would increase, not decrease, the access interval. Therefore, cache control  340  chooses a pause length shorter than a timeout period for the specific LAN communication protocol employed. As a result, the specific LAN communication protocol employed limits the degree to which dynamic flow control can be implemented. 
     In an exemplary embodiment of the invention, gateway  200 , optionally cache control  340 , introduces pauses which serve the goal of reducing the access interval. Optionally, pauses are 12 seconds or less, optionally 10 seconds or less, optionally 4 seconds or less, optionally 1 second, optionally hundreds of milliseconds, optionally tens of milliseconds, optionally 1 millisecond or less. In an exemplary embodiment of the invention, cache control imposes a plurality of pauses on a single device  150 , each pause after a successive data block. Optionally, pauses are sufficiently long that device  150  retransmits its acknowledgement 1 or more times. In an exemplary embodiment of the invention, cache control  340  counts acknowledgements for a specific packet from a specific device and transmits a next block of data only after a specific number of acknowledgements have been received. Optionally, the number of acknowledgements is determined by the specific protocol employed. Optionally, in a protocol in which n acknowledgements are sent before a repeat request is issued, cache control  340  counts (n−1), optionally n, acknowledgements before sending the next data block. 
     Potential Advantages of Access Interval Reduction 
     In order to highlight the potential advantages of reducing the access interval an illustrative example in which numerous devices  150  each request a software upgrade in a coordinated manner is presented. The software upgrade has a size of 2 MB and will be divided by SPA  220  into 4096 data blocks of 512 octets each for distribution in a TFTP LAN  170 . There are several ways in which this request may be handled. 
     In a first scenario, storage  360  has at least 2 megabytes of available space. According to this first scenario it is possible to retrieve the entire 2 megabytes, divide the content into data blocks for TFTP distribution, and cache all of the blocks. In this case, implementation of dynamic flow control interval caching permits cache control  340  to delete the first data block from storage  360  relatively soon and delete subsequent data blocks periodically after that. Deletion of blocks by cache control  340  frees a portion of storage  360  for other tasks. Alternatively or additionally, because each data block is deleted after all requesting devices  150  have received it; SPA  220  translates and relays only 1 request to server  110  in order for all the devices  150  to receive the requested software upgrade. As a result, gateway  200  rapidly becomes available for other tasks and/or resources of storage  360  become available for other uses. 
     In a second scenario, storage  360  has less than 2 megabytes of available space. According to this second scenario it is possible to retrieve a portion of the 2 megabytes, divide the retrieved portion of the content into data blocks for TFTP distribution, and cache the blocks. In this case, implementation of dynamic flow control interval caching permits cache control  340  to delete the first data block from storage  360  relatively soon and delete subsequent data blocks periodically after that. Deletion of blocks by cache control  340  frees a portion of storage  360 . Some relevant high parallelity protocols, such as HTTP, permit interruption of a request, for example when no free space in storage  360  remains, and resumption of download from a specified point at a later time. Cache control  340  takes advantage of this “interrupt/resume” feature of HTTP and issues a supplementary request for at least part of the un-retrieved content. In this way, gateway  200  and/or cache control  340  shift a storage burden for content to server  110  without interfering with efficiency of transmission of the content to device  150 . 
     Considerations in Cache Management 
       FIGS. 4A and 4B  illustrate assignment of deletion priorities to blocks of data in storage  360 . Cache controller  340  attempts to select a block for removal from storage  360  in a way that will allow SPA  220  to operate freely and to avoid selecting a block that will shortly be sent to one of devices  150 . In order to accomplish this, cache controller  340  assigns a “deletion priority” to block stored in storage  360  ( FIGS. 4A and 4B ). Cache controller  340  preferentially deletes blocks with a higher priority in order to free storage space in storage  360 . Cache controller  340  reviews and adjusts deletion priority of blocks during operation. 
     Cache control  340  may consider, for example, the following factors for each block in determining a deletion priority: sequential block number within the content resource or file, residency time in storage  360  and the number of devices  150  currently downloading the block. In TFTP, a device  150  which has acknowledged receipt of a previous block might be considered to be downloading a next block. 
     When deleting blocks from a content resource which is currently being handled by EPA  240  cache control  340  optionally employs an “interval-caching” block replacement strategy. According to the interval-caching strategy, data blocks in access interval ( 400  in  FIGS. 4A and 800  in  FIG. 4B ) are assigned a low deletion priority. Access interval  400  includes the set of blocks of a given file that lies between the block being downloaded by a device that is closest to completing the download ( 150   last ), and the device that is furthest from completing the download ( 150   first ). Optionally a default access-interval  400  is kept at the beginning of a download to permit additional devices  150  to join the download and benefit from blocks cached in storage  360  ( FIG. 4A ). The default access-interval  400  may be defined in number of blocks or by a time increment. Optionally, the default access interval is eliminated after a period of time in which no additional devices  150  have initiated download has elapsed. While the default access-interval  400  is maintained, cache control  340  may optionally delete blocks with a high deletion priority, such as those with high block numbers. Optionally, deletion priority for blocks within access interval  400  may vary. In an exemplary embodiment of the invention, the access interval corresponds to a number of blocks transferred in 10-30 seconds, optionally 15 to 25 seconds. In an exemplary embodiment of the invention, the access interval corresponds to a number of blocks transferred in about 20 seconds. Alternatively or additionally, the access interval may vary with the number of devices  150 . Optionally, a greater number of devices will produce a greater access interval. 
     Blocks which have already been received by  150   first  receive a high deletion priority because they are unlikely to be the subject of future requests from devices  150 . Optionally, those blocks in this category which have a greater residence time in storage  360  are assigned a higher priority ( FIG. 4B ). In contrast to a least recently used algorithm, a block which has been distributed to all of devices  150  receives a high deletion priority essentially immediately after it has been provided to device  150  first. In a least recently used algorithm, the deletion priority of the same block would increase slowly after the block had been distributed to  150   first . In an exemplary embodiment of the invention, cache control  340  deletes blocks which have been delivered to all relevant devices  150  before beginning to delete blocks which have not been delivered to any device. Optionally, this deletion strategy reduces a need for communication with remote server  110 . 
     In an exemplary embodiment of the invention, cache control  340  evaluates blocks for which no requests from EPA  240  have yet been received by calculating how close they are to  150   last . Optionally, blocks which are closer to  150   last  receive a lower deletion priority because EPA  240  will be requesting them sooner for transmission to one of devices  150  than blocks which are further away from  150   last . Depending upon the constraints upon storage  360 , it may be desirable to discard blocks which are far away from  150   last  and retrieve them again in the future. Optionally, a “just in time” algorithm which considers, for example, the rate of progress of  150   last  and the amount of time anticipated for receipt of a response from server  110  and/or the amount of time anticipated for translation of the HTTP packet(s) into TFTP blocks is employed in conjunction with interval caching. 
     As indicated above, cache control  340  optionally reduces the access-interval during the course of a download by implementation of dynamic flow control.  FIG. 5  is a simplified pictorial representation of how dynamic flow control helps free storage space in storage  360 .  FIG. 5  illustrates a subset of blocks of data in a content resource numbered sequentially from  500 . An example with three devices  150  is presented for clarity, although in practice the number of devices may be much larger. Conceivably, nearly any number of devices  150  might be served by storage  360  and cache controller  340 , optionally operating in the context of gateway  200  as described hereinabove. At an arbitrary time point t 1 , devices  150 F,  150  G and  150 H of LAN  170  C are accessing data blocks  501 ,  503  and  506  respectively. In the context of examples described above, each data block is a TFTP data block of 512 octets. Assuming a low bandwidth for each device  150  of 4 Kb/s, each of devices  150  will take 1 second to receive one of data blocks  501 - 508 . At time t 1 , each of devices  150  is proceeding at a similar rate, without differential allocation of bandwidth to produce dynamic flow control. As shown, this results in an access interval  400  with a width of 6 data blocks. 
     Assuming that cache control  340  employs access interval cache management at t 1  block  500  would have a very high deletion priority, blocks  507  and higher would have an intermediate deletion priority and blocks  501 - 506  (within access interval  400 ) would have a low deletion priority. This means that cache control  340  would attempt to allocate space in storage  360  corresponding to at least 6 data blocks to maintain only the access interval blocks. 
     At time t 1 +1S, cache control  340  implements differential allocation of bandwidth to produce dynamic flow control according to the present invention. When device  150  F sends a TFTP acknowledgment signal to EPA  240  indicating receipt of block  506 , cache control  340  imposes a wait of 5 seconds before beginning transmission of block  507  to device  150 F. Concurrently, when device  150  G sends a TFTP acknowledgment signal to EPA  240  indicating receipt of block  503 , cache control  340  imposes a wait of 2 seconds before beginning transmission of block  504  to device  150 G. Blocks  505  and  506  are then transmitted immediately to device  150 G upon receipt of TFTP acknowledgements for the preceding blocks. Concurrently, device  150 H sends TFTP acknowledgment signals to EPA  240  indicating receipt of block  501 - 505 , and is immediately answered by cache control  340  with transmission of the next data block. As a result, at time t 1 +5S, devices  150 F and  150 G are receiving block  507  and device  150 H is receiving block  506 . Access interval  400  has been reduced to a width of two data blocks. 
     When devices  150 F and  150 G send acknowledgements for receipt of block  507  to EPA  240 , cache control  340  imposes a one second wait on these devices. Concurrently, device  150 H receives block  506 , acknowledges receipt to EPA  240 , receives block  507  and acknowledges receipt to EPA  240 . Again, cache control  340  does not impose any wait on device  150 H. As a result, at time t 1 +6S, all of devices  150 F,  150 G and  150 H begin receiving block  508  from storage  360 . Access interval  400  has been reduced to one block ( 508 ). 
     The above example has been provided for clarity of illustration only. Actual data transfer rates may be much higher, for example, 64 kbps or more. 
     Alternatively or additionally, if access interval  400  becomes too large, devices  150  may be split into two or more groups, each group being defined by a separate access interval and subject to dynamic flow interval caching as described hereinabove. Optionally, the interval between groups may be reduced using the principles of dynamic flow control as detailed hereinabove. Criteria for defining groups may vary, for example with size of storage  360 , number of devices  150 , the specific low parallelity and/or insecure protocol employed, initial access interval  400 , the specific low parallelity and/or insecure protocol employed and available bandwidth outside the LAN. In an exemplary embodiment of the invention, cache control  340  divides devices  150  into groups if a continuous sequence of 10, optionally 20, optionally 50, optionally 100 or more blocks which are not currently being sent to any device  150  is detected. 
     The present invention relies upon execution of various commands and analysis and translation of various data inputs. Any of these commands, analyses or translations may be accomplished by software, hardware or firmware according to various embodiments of the invention. In an exemplary embodiment of the invention, machine readable media contain instructions for translation of a low parallelity and/or insecure protocol request to a high parallelity and/or secure protocol request, and/or translation of a high parallelity and/or secure protocol response to a LAN response and/or implementation of dynamic flow control of data blocks stored in a cache. In an exemplary embodiment of the invention, a CPU executes instructions for translation of a low parallelity and/or insecure protocol request to a high parallelity and/or secure protocol request, and/or translation of a high parallelity and/or secure protocol response to a LAN response and/or implementation of dynamic flow control of data blocks stored in a cache. 
     In the description and claims of the present application, each of the verbs “comprise”, “include” and “have” as well as any conjugates thereof, are used to indicate that the object or objects of the verb are not necessarily a complete listing of members, components, elements or parts of the subject or subjects of the verb. The present invention has been described using detailed descriptions of embodiments thereof that are provided by way of example and are not intended to necessarily limit the scope of the invention. In particular, numerical values may be higher or lower than ranges of numbers set forth above and still be within the scope of the invention. Alternatively or additionally, portions of the invention described/depicted as a single unit may reside is two or more separate physical entities which act in concert to perform the described/depicted function. Alternatively or additionally, portions of the invention described/depicted as two or more separate physical entities may be integrated into a single physical entity to perform the described/depicted function. The described embodiments comprise different features, not all of which are required in all embodiments of the invention. Some embodiments of the invention utilize only some of the features or possible combinations of the features. Variations of embodiments of the present invention that are described and embodiments of the present invention comprising different combinations of features noted in the described embodiments can be combined in all possible combinations including, but not limited to use of features described in the context of one embodiment in the context of any other embodiment. The scope of the invention is limited only by the following claims.