Patent Publication Number: US-10769059-B2

Title: Apparatus and system for object-based storage solid-state device

Description:
CLAIM OF PRIORITY 
     This application is a continuation of co-pending U.S. Ser. No. 15/199,674 filed Jun. 30, 2016, which is a continuation of U.S. Ser. No. 13/775,216 filed Mar. 2, 2013 (now U.S. Pat. No. 9,824,006), which is a continuation of U.S. Ser. No. 13/118,418 filed May 28, 2011 (now U.S. Pat. No. 8,402,152), which is a continuation of U.S. Ser. No. 12/319,096 filed Dec. 31, 2008 (now U.S. Pat. No. 7,970,919), which claims priority to U.S. Ser. No. 61/011,899 filed Jan. 22, 2008, and this application is a continuation-in-part of Ser. No. 11/891,741 filed Aug. 13, 2007 (now abandoned), all incorporated by reference herein and all benefits of all priorities hereby claimed. 
    
    
     COPYRIGHT NOTICE 
     A portion of the disclosure of this patent document may contain material which is subject to copyright protection. The copyright owner has no objection to the facsimile reproduction by anyone of the patent document or the patent disclosure, as it appears in the Patent and Trademark Office patent file or records, but otherwise reserves all copyright rights whatsoever. 
     FIELD OF THE INVENTION 
     This invention relates to object-based storage devices (OSDs), and more particularly to object-based storage systems. 
     BACKGROUND 
     The subject matter discussed in the background section should not be assumed to be prior art merely as a result of its mention in the background section. Similarly, a problem mentioned in the background section or associated with the subject matter of the background section should not be assumed to have been previously recognized in the prior art. The subject matter in the background section merely represents different approaches, which in and of themselves may also be inventions. 
     In various conventional storage systems, rotating magnetic media is used. While the density of such rotating media has increased with demand for storage, the mere fact that the system has mechanically moving parts makes the system inherently subject to reliability problems, and inherently slow, slow, at least relative to the speed of moving electrons. Conventional approaches to mitigating the inherent limitations of rotating storage media have included the creation of arrays of redundant independent disks (RAID). Many advances in RAID-related technologies have resulted in a well understood corpus of techniques for RAID that address reliability and speed. 
     Concurrent with advances in storage subsystems, are advances in the taxonomy of stored items. Whereas traditionally a stored item is viewed by the operating system as just a sequence of blocks of binary data, prescient operating system design considers stored objects as having many more attributes than merely a sequence of blocks of binary data. Of course with a more specific taxonomy of stored items comes additional capabilities (and speed requirements) for the operating system to pre-process data before presenting to a user or to an application. Commercially viable solid-state memory systems based on DRAM, while much faster than rotating media, exhibit another set of limitations, including (depending on the specific technology or techniques employed) volatility and cost. 
     Meanwhile, trends in manufacturing of certain solid-state memory devices portend higher densities, inherently higher reliability, and higher speeds, while delivering functionality at lower power and lower costs such as NAND flash memory. However, commercially available consumer grade external storage devices have limited storage host attach interfaces (e.g. USB or 1394), and controllers that are typically included with FLASH devices are only very modest in capability. 
     Even given the viable storage technologies, access and transfer speeds are still far slower than users accept when the aforementioned pre-processing techniques are employed. Moreover in many commercial embodiments, multiple interfaces (especially interfaces of differing types) are preferred. 
     These and other limitations foster the notion to combine the concepts of object-based storage techniques with high-performance solid-state based storage. Consideration of object-based storage algorithms executing on storage host attach interfaces, together with solid-state memory systems, results in an avalanche of ideas and inventions which are the subject matter of the detailed descriptions of embodiments herein. 
     SUMMARY 
     The invention provides for a storage physical interface and is characterized by a control module capable of processing object storage device algorithms. The storage physical interface is characterized by a control module capable of processing object storage device algorithms and is further characterized by including at least one solid-state non-volatile memory chip array. 
     In accordance with embodiments, there are provided techniques for providing multiple interfaces in a solid-state based storage system employing OSD techniques. Embodiments include providing for multiple interfaces in a solid-state device (SSD) storage system within a freestanding storage cabinet, or in a desk side chassis, or in an industry-standard drawer-type form factor, or in a consumer device (e.g. digital camera, smartphone, handheld game console), or even in miniaturized or custom form factors. 
     Any of the above embodiments may be used alone or together with one another in any combination. Inventions encompassed within this specification may also include embodiments that are only partially mentioned or alluded to or are not mentioned or alluded to at all in this brief summary or in the abstract. Although various embodiments of the invention may have been motivated by various deficiencies with the prior art, which may be discussed or alluded to in one or more places in the specification, the embodiments of the invention do not necessarily address any of these deficiencies. In other words, different embodiments of the invention may address different deficiencies that may be discussed in the specification. Some embodiments may only partially address some deficiencies or just one deficiency that may be discussed in the specification, and some embodiments may not address any of these deficiencies. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       In the following drawings like reference numbers are used to refer to like elements. Although the following figures depict various examples of the invention, the invention is not limited to the examples depicted in the figures. 
         FIG. 1A  illustrates a block diagram of an environment where an apparatus for providing a solid-state based storage device with multiple interfaces might be used, according to one embodiment. 
         FIG. 1B  illustrates a block diagram of a software stack for providing a solid-state based storage array with multiple interfaces, according to one embodiment. 
         FIG. 2  illustrates a block diagram of an embodiment of a solid-state based storage device. 
         FIG. 3  illustrates an embodiment of a controller card as an exemplary implementation of a solid-state based storage device with multiple interfaces. 
         FIG. 4  illustrates exemplary configurations of an apparatus for providing a solid-state based storage device, according to one embodiment. 
         FIG. 5  illustrates a block diagram of an embodiment of a networked environment wherein an apparatus for providing a solid-state based storage device with multiple interfaces might be used. 
         FIG. 6  illustrates a method for configuring a solid-state based storage device, according to one embodiment. 
         FIG. 7  depicts a storage subsystem connected to a host, according to one embodiment. 
         FIG. 8  depicts an exemplary configuration of an object-based, solid-state based storage device, according to one embodiment. 
         FIG. 9  illustrates a method for configuring a solid-state based storage device, according to one embodiment. 
         FIG. 10  illustrates a method for executing a command to an object-based storage device, according to one embodiment. 
     
    
    
     DETAILED DESCRIPTION 
     General Overview 
     Systems and methods are provided for an apparatus for providing a solid-state based storage device with multiple interfaces. Apparatus and methods are disclosed herein, with emphasis on disclosure of embodiments to provide features related to a solid-state based storage device with multiple interfaces and techniques to enable additional enhanced services in conjunction with the traditional use of a storage device. In accordance with embodiments, there are provided techniques for providing multiple interfaces in a solid-state based storage system employing OSD techniques. Embodiments include providing for a solid-state device (SSD) storage system within a freestanding storage cabinet, or in a desk side chassis, or in an industry-standard drawer-type form factor, or in a consumer device (e.g. digital camera, smartphone, handheld game console), or even in miniaturized or custom form factors. 
       FIG. 1A  illustrates a block diagram of an environment where an apparatus for providing a solid-state based storage device with multiple interfaces might be used. In particular,  FIG. 1A  depicts a computer system  102  (e.g. desktop personal computer, desk side personal computer, server, DVR, NVR, PVR, media server, game console such as an Xbox™ or Wii™ entertainment center, or any other consumer device employing non-volatile memory, digital camera, smartphone, handheld game console, mobile handheld device, etc.) connected to a solid-state based storage device  104  through at least one interface in operation through connection  105 . Strictly as an option, the solid-state based storage device  104  may feature multiple solid-state disk drives  122   1  through  122   N . Embodiments of the solid-state based storage device  104  may include multiple interfaces  118   1  through  118   N , capable to serve at least two distinct input-output interface types. Embodiments of the solid-state based storage device  104  may include multiple controllers  120   1  through  120   N . The computer system may include a CPU or GPU  106 , and may further include random access memory  108 , provided as internal or external random access memory or both. In some embodiments, the computer system  102  may contain a local hard disk drive (HDD) storage. As an optional feature, the computer system  102  may contain a host bus adapter  112  and a client agent  114 . As will be described in the following, the host bus adapter may be as simple as a physical layer interface, or it may be more complex, involving both firmware and software, or any degree of complexity or simplicity. Similarly, the client agent  114  may be implemented in or on any element included in the computer system  102  that is capable of executing software or firmware. In this exemplary environment, the components  102  and  104  each include firmware or software or both as is presently described. 
       FIG. 1B  depicts a block diagram of a software stack. Strictly as an option in some embodiments, software applications  152  execute on computer system  102  possibly using any services as may be provided by one or more operating system (OS) kernels  154   1 - 154   N . The OS kernel, in turn may use any services as may be provided by the drivers  156   1  through  156   N . 
     In addition to the aforementioned software stack components  152 ,  154 , and  156 , the solid-state based storage device with multiple interfaces  104  may itself include a collection of software or firmware, which may be organized into multiple images or multiple instances as depicted in elements  158   1  through  158   N . Additionally, there may be firmware or software or even an entire stack of software embedded in, or executing on, or adapted to execute on or in or with the one or more solid-state disk drives  122 . 
       FIG. 2  shows an example embodiment of a solid-state based storage device  104  as shown in  FIG. 1 , and similarly again in the embodiment of  FIG. 2 . In the method  200 , the embodiment includes a carrier or chassis  202  which may be a physical chassis, or a motherboard, or a daughter-card or any other printed circuit board (PCB). The chassis  202  serves to orient and connect one or more controllers  204 ,  206  to an array of solid-state based storage devices  210 . In some embodiments, there may be a plurality of controllers  204 ,  206  configured to provide enhanced reliability. As one skilled in the art will readily recognize, the techniques and capabilities employed in a RAID array of spinning drive elements can be similarly employed in the situation where solid-state based storage devices are employed as RAID elements of RAID sets. In the example shown, a controller  204  is in communication with every element in the array of solid-state based storage devices  210 . Also as shown, strictly as an option to provide redundancy, a second or nth controller  206  is in communication with every element in the array of solid-state based storage devices  210 . The solid-state based storage devices  210  may be implemented by using one or more types of solid-state based storage devices, including flash-based SSDs (whether NAND or other flash technology), or other solid-state based storage devices, or whether or not the SSDs include a SATA, or SATA2, or SAS, or IDE, or other interface. 
       FIG. 3  illustrates a system  300  for an interface  118 . The exemplary embodiment shown includes a plurality of input-output interfaces,  304 ,  306 ,  308 , as shown. Each of the plurality of input-output interfaces  304 ,  306 ,  308  are in communication with at least one input-output controller  310  adapted for implementation of the specific type or types of input-output carried out over the plurality of interfaces  304 ,  306 ,  308 . In this embodiment, any known input-output interface may be implemented by the input-output interfaces and input-output controller, and may implement at least two interfaces, including, eSATA, 802.3x, Ethernet, 802.11a, 802.11b, 802.11g, 802.11n, USB, USB 1.x, USB 2.x, IEEE 1394, Firewire™, PCI Express (per PCI-SIG) using internal or external cabling or any other known communication system. One or more of these interfaces  304 ,  306 ,  308  may be enabled or disabled at any time. Or, one or more connections, whether physical or logical connections may be concurrently enabled at any time. With respect to wireless interfaces (e.g. 802.11x) the encryption security may be enabled or disabled. 
     The signals  309  are carried out over connections (whether physical connections or logical connections) to and from input-output controller  310  and to and from the plurality of interfaces  304 . The input-output controller serves to implement aspects of the communication protocol including (optionally) aspects of the data link, network layer, transport layer, session layer, presentation layer, application layer, and/or aspects of routing protocols. Moreover, the input-output controller  310  is adapted to communicate over signals  312  to at least one storage controller  314 . 
     Strictly as an option, the controller  302  may implement a processor  316  separate from the input-output controller  310  and storage controller  314 . Such a processor  316 , if present may be in communication with the input-output controller  310  and/or the storage controller  314 . To the extent that the aforementioned aspects of the communication protocol are not implemented by the input-output interfaces  304 ,  306 ,  308  and/or input-output controllers  310 , the processor  316  may be employed to implement aspects of the protocol. Examples of the input-output protocol may include network attached storage (NAS) and/or internet small computer storage interface (iSCSI). Additionally, to the extent that the aforementioned aspects of the communication protocol are not implemented by the input-output interfaces and/or input-output controllers  310 , the processor  316  may implement or emulate some of all aspects of CIFS or NTFS, or NFS or any other file system. 
     Strictly as an option, the controller  302  may implement a processor  316  separate from the input-output controller  310  and storage controller  314 . Such a processor  316 , if present may be in communication with the input-output controller  310  and/or the storage controller  314 . To the extent that the aforementioned aspects of the communication protocol are not implemented by the input-output interfaces  304 ,  306 ,  308  and/or input-output controllers  310 , the processor  316  may be employed to implement some or all aspects of a variety of storage applications. Strictly as an option the controller  302  may be implemented as collection of discrete components combined on a carrier, or may be implemented as a single semiconductor platform. It should be noted that the term single semiconductor platform may also refer to multi-chip modules. Of course, the various modules may also be situated separately or in various combinations of semiconductor platforms or carriers. 
     In the specific case of implementation of aspects of a variety of storage applications via execution of software or firmware in or on the storage controller  314  and/or in or on the processor  316 , the controller  314  and/or the processor  316  serves to communicate with client agent  114  to carry out the aforementioned aspects of a variety of storage applications. 
     One or more storage controller(s)  314  is capable of running in non-RAID and RAID mode with different levels (0, 1, 3, 5, 6, 10), and interfaces to at least one SSD interface  320  over signals  318 . In some implementations there will be exactly one SSD interface  320 . In other implementations, there may be more than one SSD interfaces  320 . In preferred embodiments the number of SSD interfaces is defined by the specific RAID configuration implemented 
     The elements  330   1  through  330   n  as shown in the exemplary embodiment of  FIG. 3  are solid-state storage devices (SSD) and are individually in communication to an interface  320  over signals  322 . The SSDs  330   1  through  330   n  may all be identical instances of the same SSD, or they may be arbitrarily sized and configured, so long as they properly conform to the interface characteristics of the corresponding interface  320 . As an option, the storage controller  314  may communicate with an expansion port  336  for provision of storage capacity in addition to the storage capacity of SSDs  330   1  through  330   n . 
       FIG. 4  shows a possible configuration of a storage enclosure. The free-standing storage enclosure shown in  FIG. 4  is strictly an option, and other embodiments of a solid-state based storage device are not only possible, but also disclosed herein. The system  400  includes a free-standing enclosure  401 , and further includes at least one interface  418 . In some configurations, of the enclosure  401 , the enclosure is adapted with one or more bays which conform to all mechanical, electrical, and other requirements to comport with the SATA2 hard disk carrier form factor. See element  402   1  through  402   n . Strictly as an option, one or more of such bays, or bays of a form factor other than SATA2 hard disk carrier form factor are populated with one or more SSD devices. It must be emphasized that the form factor of any existing or prophetic SSD device may be (either individually or in some physical combination) of a different size than the devices intended to populate the SATA2 bay; accordingly, an arbitrary number of SSD devices can be arranged, connected, mounted, stacked, or otherwise adapted to fit into the bays  402   1  through  402   n  As an alternative embodiment, the enclosure  401  might be electrically and mechanically designed to fit into a handheld consumer device (e.g. digital camera, smartphone, handheld game console), in which case the interface  418  might be a Compact Flash interface, a SATA interface, a PCI-Express interface, an ATA interface, an IDE interface, or even a wireless interface adapted for memory accesses. 
     The system  400  may be adapted with one or more bays which conform to any mechanical, electrical, and other requirements to comport with the drive form-factors other than a SATA form-factor. 
     Strictly as an option the method of  400  or other embodiments discussed herein may include an expansion interface  406  suited to comport to one or more storage device standards, including SATA, SATA2, wired Ethernet including gigabit Ethernet and 10 gigabit Ethernet. As an option, this expansion interface  406  is provided to permit expansion of storage capacity using storage devices attached to the expansion interface  406 . Alternatively, expansion  406  might be a port of the same (or different) type as the interface  418 , and be adapted for memory capacity or performance expansion. 
     In some embodiments of a solid-state based storage device, the enclosure may contain one or more printed circuit boards (PCBs), daughter-cards, sub-chassis, carriers  408   1  through  408   n  designed or adapted to provide a physical mounting as well as electrical connectivity with, and to, and from any components used in elements  402   1  through  402   n ,  406 , and/or interface  418 . 
     As mentioned in the discussion herein regarding  FIG. 4 , the free-standing chassis embodiment is one of a multitude of possible physical design configurations. In addition to a multitude of free-standing chassis configurations, the solid-state based storage device may be enclosed in other chassis as may be present for enclosure of elements  102 , or  104  of  FIG. 1A . In fact, inasmuch as the solid-state based storage device of  FIG. 2  or  FIG. 3 , or  FIG. 4  can be partitioned, some portion of the solid-state based storage device may be enclosed in one chassis among  102 ,  104 , while the remaining portions may be enclosed in a different chassis. 
     While  FIG. 4  depicts the aspect ratio of a ‘tower’ enclosure, the enclosure need only be as large as is needed to package the elements of system  300 . In one such packaging option, the size and aspect ratio is similar to the size and aspect ratio of a 3.5 inch hard disk drive (HDD). In some cases, strictly as an option the aforementioned package may fit mechanically and electrically into a 3.5 inch HDD bay. Similarly, in one packaging option, the size and aspect ratio is similar to the size and aspect ratio of a 2.5 inch hard disk drive (HDD). In some cases, strictly as an option the aforementioned package may fit mechanically and electrically into a 2.5 inch HDD bay. In yet another embodiment the package may conform to the 3.5 inch or 2.5 inch drive bay physical requirements, and yet be free-standing. In yet another embodiment, the elements of system  300  might be packaged into a form factor only as large as required to house the needed elements. 
     Returning attention to  FIG. 3  as is herein disclosed, the input-output controller  310  communicates to and from one or more of the plurality of interfaces  304 ,  306 ,  308 . Accordingly the input-output controller  310  may implement a method to select from the plurality of interfaces  304 ,  306 ,  308 . One skilled in the art will recognize that whereas selection of hard-wired interfaces has been traditionally performed using a physical or logical multiplexor, the inclusion of the aforementioned one or more wireless protocols implies that a method to select not only the interfaces from among the plurality of interfaces but possibly also from one or more specific wireless networks that may be reachable over the plurality of interfaces. Accordingly the method  600  of  FIG. 6  is herein disclosed. 
       FIG. 5  illustrates an environment wherein an apparatus for providing a solid-state based storage device with multiple interfaces might be used. In this exemplary network topology, one or more solid-state based storage devices  502  and  504  are in communication with one or more CPUs  506  or GPUs  508  or other computing subsystem such as a server, or personal computer or any variety of handheld consumer devices. Such a personal computer or server or CPU  506  or GPU  508  contains a client agent  507  capable to handle at least one function involved in the communication carried out over the path  522 . In some environments, the one or more CPUs  506  or GPUs  508  may optionally be connected to network  526 . Further, in some environments, the one or more CPUs  506  or GPUs  508  may optionally be connected to storage device  502  via connection  525  which is distinct from the network connection  524 . 
     The interconnect fabric  510  may operate to execute multiple physical layers, multiple link layers, multiple protocols and multiple modes of session management. In the embodiment shown, a storage device  502  may be in communication through an interconnect network  510  via an interface  520  using a connection  518 . As shown, concurrently a second or Nth solid-state based storage device  504  may be in. communication through an interconnect network  510  via an interface  519  using a connection  525 . Strictly as an option, yet another storage apparatus  512  which may not be a solid-state based storage array may be present in the environment. 
     In one embodiment plural solid-state based storage devices may be present and used as at least two nodes in said network topology. Strictly as an option, a network topology with plural solid-state based storage devices may implement secondary backup storage discussed infra. Moreover, the solid-state based storage device may be shared by one or multiple users as primary, backup, or as secondary backup storage, or as media storage, or as shared storage of any type of data or media files. 
       FIG. 6  depicts a method to select a subset of user-specified interfaces from a plurality of possible interfaces. Specifically, the method  600  begins by accepting user-specified preferences. See operation  602 . The operation  602  may employ one or more techniques, including use of a profile, use of a GUI, use of an import filter, or use model heuristics, and/or use of any known technique to confirm with or derive from the user the user&#39;s preferences. The method  600  continues by mapping the user preferences to the available input-output interfaces, resulting in an input-out controller configuration. See operation  604 . Next, the resulting input-output controller configuration is mapped to the available storage controller configurations. That is, the operation  606  operates by mapping the input-output controller configuration result of operation  604  to the storage controller. 
     Some examples of the operation  602  may include accepting user-specified preferences from a GUI or configuration file. In some embodiments, a configuration file with default values of settings and preferences is provided and may or may not be modified by the user. Specific cases of user-specified input may include user selection of the location for primary storage, search characteristics for tags in an OSD configuration, tag creation options, selection of adaptive tagging options, option selection for capturing specific media types in specific OSD formats, etc. In this case, the default preference may be to move or otherwise store data found on any local storage device to the SSD, and henceforth use the SSD as primary storage. Another user selection may include options for backup. More specifically, through strictly as an option, the user may specify a variety of backup configuration options, including what data to backup, the frequency of backup, the naming conventions to be used in naming backed-up data, and the specific target location on one or more SSDs. Another option is that the SSD storage device may utilized for media sharing and being accessed by multiple users (CPU or GPU based) via a network. In this case any user can utilize the device as primary, back-up, or secondary storage. In exemplary cases involving more than one SSD storage device volumes, operation  602  captures user options regarding secondary backup storage where a second or nth copy of backed-up data is stored on one of more secondary SSD storage device volumes. Of course a secondary SSD storage device volume may include multiple SSDs, or it may include multiple SSD storage arrays, or it may merely include a directory or other file on a single SSD. 
       FIG. 7  shows a conventional solid-state based storage device  704  connected to a host system  701  via a storage physical layer interface  703 . Generally speaking, conventional solid-state based storage devices employ a controller for processing algorithms for physical storage device management (e.g. wear-leveling)  718 . Also, conventional solid-state based storage devices contain one or more solid-state non-volatile memory devices (e.g. NAND or other flash memory devices). 
       FIG. 8  shows a method  800  including a host system  802  which employs a partition for executing applications  806 , a system call interface  807 , an OSD storage driver  801 , an OSD call interface  808 , and an inter-system physical layer interface  809  (e.g. SATA, SAS, PATA, Fibre-channel, SCSI, IDE, etc.) for communicating to/from an OSD-SSD  804  over an inter-system communication media  810  (e.g. copper wire, fibre, or wireless media). The OSD-SSD in turn comprises a storage physical interface communication link  811 , a control module capable of processing algorithms for OSD  812  combined with processing of physical storage device management algorithms  818 , and at least one group of solid-state non-volatile memory devices  820 . 
     In embodiments, the OSD-SSD controller ( 812 ) may be a uniprocessor or a multi-processor; in particular, the OSD algorithms and physical storage device management algorithms are adapted to execute on the same control processor or processors  816 . In one embodiment, the OSD algorithms perform the storage management component which maps logical constructs (e.g. files or database entries) to the physical organization of the storage media. In the OSD model, the logical constructs are called user objects. In addition to mapping data, the storage management component maintains other information about the OSD objects that it stores (e.g. size, and usage quotas, and associated username) in attributes. The user component may have the ability to influence the properties of object data through the specification of attributes (e.g. directing that the location of an object be in close proximity to another object or have some higher performance characteristic) via mechanisms that are known in the art. 
     In other embodiments the OSD algorithms operate on the data or the protocol for communicating or processing data so as to implement mapping functions, storage functions, metadata definitions, assignment and storage functions, and user-specific functions. In fact, in some embodiments the OSD algorithms are known only by a code that maps to a specific implementation; for example a code of value “xyz123” might be redirected to an algorithm available via internet access at an address such as http://abc.osdalgorithms/xyz123. 
     Of course, an OSD algorithm may be implemented in a single processor, or in multiple processors, or may even be implemented in multiple processors situated in different subsystems in communication with each other across the inter-system media communication link  810 . 
     In some embodiments, the partition for executing applications  806  may be a logical partition of an operating system such as user space, or it may be a combination of partitions of an operating system including both user space and kernel space. In other embodiments, the partition may itself be a processor or controller, or a plurality of processors or controllers. The partition as envisioned in various embodiments may be strictly a virtual construction, and may in fact be comprised of any combination of logical partitions and physical partitions, possibly involving any number of processors or controllers. 
     The system call interface  807  of  FIG. 8  may be the system interface as delivered in any version of any known operating system, including any version or descendant of Microsoft Windows, any version or descendant of UNIX or any version or descendant of Linux, or of any embedded operating system, whether commercially available or not. 
     The OSD interface  808  is adapted to interface to the system call interface  807  as well as the OSD interface  808  and further, as an implementation choice may be adapted to interface with the storage physical interface  809 . In embodiments, the OSD interface  808  may merely transmit commands or information between the system call interface  807  and the storage physical interface  809 , or it may operate on the information before passing those commands or information. 
     The storage physical interface  811  may include any generation of SATA, SAS, PATA, Fibre-channel, SCSI, IDE, Compact Flash, PCI-Express, or even USB, IEEE, FireWire, Ethernet, Gigabit Ethernet, or any serial or parallel physical interface capable of transmission over electrically conductive media or over light transmitting media or even over a wireless medium, possibly using any one or more wireless standards (e.g. Bluetooth, 802.11, Wi-Fi, WiMAX, etc.). 
     In various embodiments, the inter-system physical layer interface communication link  810  may be identical to the storage physical interface  811 , or the inter-system physical layer interface communication link  810  may include any combination of implementations of storage physical interface  811 , or may include the use of other techniques for inter-system connectivity. 
     The control module is capable of processing algorithms for the OSD  812 . The algorithms may be adapted to make use of any OSD formats, or of any portion or subset of the standard known as T10-OSD protocol format, also known as the OSD T10-standard, and heretofore known by such aliases including the shortened form, T10-OSD. Moreover, any portion or combination of components or functions of the OSD-SSD  804  and/or the host  802  may be fully or partially T10-OSD compliant. 
     The solid-state non-volatile memory devices  820  may be implemented in various embodiments such as flash storage, or it may be implemented using any known method for providing a non-volatile capability to any digital storage device or media. Actual embodiments and envisioned embodiments include support for a wide range of storage media, including NAND flash (all variants expressly including MLC and SLC) and other non-volatile memory, regardless of the SSD technology employed and regardless of if the non-volatile characteristic is implemented using the charged gate technique or other techniques such as battery-powered semiconductor memory. 
     In exemplary embodiments, the OSD-SSD may employ a controller  816  that is an embedded controller, a uniprocessor, or the controller  816  may be implemented as a multi-processor array of loosely- or tightly-coupled processors. 
     Once the host system and OSD-SSD are initialized, any command set per the T10-OSD specifications may be executed (e.g. READ and WRITE). As an option (but not a requirement or limitation), the READ command requests that the device server return data to the application client from the specified user object, and the WRITE command causes the specified number of bytes to be written to the specified user object at the specified relative location. In other embodiments, and indeed in normal operation of exemplary embodiments, the READ and WRITE commands may take on any other variations as are known in the art. 
     It is observed that for a broad class of stored objects, the object is written and thence retrieved, or searched, or filtered, or used in a join operation or in a projection, or used in any other manner in queries many times. The asymmetric characteristic therein is known as asymmetric storage object access. As will be readily recognized by those skilled in the art, the apparatus and methods herein described support asymmetric storage object access. In various embodiments, this asymmetry is exploited in processing of video files, music files, database files, emails, forms, and virtually any type of file intended to be retrieved multiple times on the basis of some criteria capable of being formulated into a query. Stated in other terms, the act of writing a storage object may include pre-processing the file to produce tags, the tags then being formatted as part of the object (including the data of file), and the act of reading the object (or group of objects) may include retrieval on the basis of querying the tags or metadata or other aspects associated with the object (or group of objects). 
       FIG. 9  shows one embodiment of a method for initializing a device for use in object-based storage. Using any computer coding techniques, the method for configuring an object-based storage device onto a host processor might comprise steps for determining the host system characteristics (see operation  902 ); determining connected communication OSD device characteristics (see operation  904 ); installing at least one OSD interface onto the host (see operation  906 ); determining connected communication device logical characteristics (see operation  908 ); configuring OSD interfacing requirements, possibly with user-specified configurations parameters, and possibly interactively with a user through a computer-user interface such as a GUI (see operation  910 ); and initializing solid state devices (see operation  912 ). Of course the steps included in system  900  can be performed in any particular order, or even in parallel, or even some in parallel and some serially. 
     Of course the steps for determining host system characteristics might be performed by an instance of a CPU on the host system  802 , and more specifically by any one or more software code segments for an OSD interface  808 , an OSD storage driver  801 , any part of a system call interface  807  or transaction therethrough, or even from one or more applications running on host system  802 . Alternatively, or in combination with the foregoing host-based components ( 808 ,  801 ,  807 ,  806 ), one embodiment of a method for initializing a device for use in object-based storage might include software code for an OSD interface that resides on an OSD-SSD device  804 , including any one or more hierarchical blocks  811  or  816 , or even in conjunction with code or interfaces incorporated into flash devices  820 . 
     In fact, it is reasonable, envisioned, and exemplified in  FIG. 10  that code or interface hardware residing on the OSD-SSD  804  might be configured for accepting storage commands from a system call interface (see operation  1002 ) of a host  802 , translating storage commands from the host into storage commands for an OSD-SSD device (see operation  1004 ), initiating a second communication protocol between the host and the OSD-SSD (see operation  1006 ), and communicating results from execution of the second protocol (see operation  1008 ) to the host  802 . In some cases, translation of a storage command (or a combination of storage commands) from the host into storage commands for an OSD-SSD device might include translating onto a different protocol, and such a different protocol might in turn include expansion of a single protocol command into multiple protocol commands. Similarly, any module capable of performing the operation  1004  might receive multiple storage commands from the host into fewer storage commands, or even a single storage command for an OSD-SSD device. 
     In another embodiment, the method  1000  for initializing a device for use in object-based storage might be employed to adapt legacy storage devices to accept OSD commands. In particular, an OSD device might be constructed by using a legacy device capable of responding to commands over the inter-system communication link media  810 . In generalized cases, modifications might be made to such a legacy device in the form of software modification, or hardware modification to a storage physical interface  811 , or modification to a controller  816  to include OSD-specific command handlers, and/or modification to one or more members of the non-volatile storage device  820 . 
     While the invention has been described by way of example and in terms of the specific embodiments, it is to be understood that the invention is not limited to the disclosed embodiments. To the contrary, it is intended to cover various modifications and similar arrangements as would be apparent to those skilled in the art. Therefore, the scope of the appended claims should be accorded the broadest interpretation so as to encompass all such modifications and similar arrangements.