WinFS (short for Windows Future Storage) [1] was the code name for a canceled [2] data storage and management system project based on relational databases, developed by Microsoft and first demonstrated in 2003. It was intended as an advanced storage subsystem for the Microsoft Windows operating system, designed for persistence and management of structured, semi-structured and unstructured data.
WinFS includes a relational database for storage of information, and allows any type of information to be stored in it, provided there is a well defined schema for the type. Individual data items could then be related together by relationships, which are either inferred by the system based on certain attributes or explicitly stated by the user. As the data has a well defined schema, any application can reuse the data; and using the relationships, related data can be effectively organized as well as retrieved. Because the system knows the structure and intent of the information, it can be used to make complex queries that enable advanced searching through the data and aggregating various data items by exploiting the relationships between them.
While WinFS and its shared type schema make it possible for an application to recognize the different data types, the application still has to be coded to render the different data types. Consequently, it would not allow development of a single application that can view or edit all data types; rather, what WinFS enables applications to do is understand the structure of all data and extract the information that they can use further. When WinFS was introduced at the 2003 Professional Developers Conference, Microsoft also released a video presentation, named IWish, [3] showing mockup interfaces that showed how applications would expose interfaces that take advantage of a unified type system. The concepts shown in the video ranged from applications using the relationships of items to dynamically offer filtering options to applications grouping multiple related data types and rendering them in a unified presentation.
WinFS was billed as one of the pillars of the "Longhorn" wave of technologies, and would ship as part of the next version of Windows. It was subsequently decided that WinFS would ship after the release of Windows Vista, but those plans were shelved in June 2006, [4] with some of its component technologies being integrated into ADO.NET and Microsoft SQL Server. [5]
Many filesystems found on common operating systems, including the NTFS filesystem which is used in modern versions of Microsoft Windows, store files and other objects only as a stream of bytes, and have little or no information about the data stored in the files. Such file systems also provide only a single way of organizing the files, namely via directories and file names. [6] [7]
Because a file system has no knowledge about the data it stores, [6] applications tend to use their own, often proprietary, file formats. This hampers sharing of data between multiple applications. It becomes difficult to create an application which processes information from multiple file types, because the programmers have to understand the structure and semantics of all the files. [8] Using common file formats is a workaround to this problem but not a universal solution; there is no guarantee that all applications will use the format. Data with standardized schema, such as XML documents and relational data fare better, as they have a standardized structure and run-time requirements. [9]
Also, a traditional file system can retrieve and search data based only on the filename, because the only knowledge it has about the data is the name of the files that store the data. [8] A better solution is to tag files with attributes that describe them. Attributes are metadata about the files such as the type of file (such as document, picture, music, creator, etc.). [6] This allows files to be searched for by their attributes, in ways not possible using a folder hierarchy, such as finding "pictures which have person X". The attributes can be recognizable by either the file system natively, or via some extension. [6] Desktop search applications take this concept a step further. They extract data, including attributes, from files and index it. To extract the data, they use a filter for each file format. This allows for searching based on both the file's attributes and the data in it. [6]
However, this still does not help in managing related data, as disparate items do not have any relationships defined. For example, it is impossible to search for "the phone numbers of all persons who live in Acapulco and each have more than 100 appearances in my photo collection and from whom I have had e-mail within the last month". Such a search could not be done unless it is based on a data model which has both the semantics as well as relationships of data defined. [6] [7] WinFS aims to provide such a data model and the runtime infrastructure that can be used to store the data, as well as the relationships between data items according to the data model, doing so at a satisfactory level of performance.
WinFS natively recognizes different types of data, such as picture, e-mail, document, audio, video, calendar, contact, rather than just leaving them as raw unanalyzed bytestreams (as most file systems do). Data stored and managed by the system are instances of the data type recognized by the WinFS runtime. The data are structured by means of properties. For example, an instance of a résumé type will surface the data by exposing properties, such as Name, Educational Qualification, Experience. Each property may be a simple type (strings, integers, dates) or complex types (contacts). [8] [10] Different data types expose different properties. Besides that, WinFS also allows different data instances to be related together; such as a document and a contact can be related by an Authored By relationship. [7] [10] Relationships are also exposed as properties; for example if a document is related to a contact by a Created By relationship, then the document will have a Created By property. When it is accessed, the relationship is traversed and the related data returned. [10] By following the relations, all related data can be reached. [7] WinFS promotes sharing of data between applications by making the data types accessible to all applications, along with their schemas. [8] When an application wants to use a WinFS type, it can use the schema to find the data structure and can use the information. So, an application has access to all data on the system even though the developer did not have to write parsers to recognize the different data formats. It can also use relationships and related data to create dynamic filters to present the information the application deals with. The WinFS API further abstracts the task of accessing data. All WinFS types are exposed as .NET objects with the properties of the object directly mapping to the properties of the data type. [6] Also, by letting different applications that deal with the same data share the same WinFS data instance rather than storing the same data in different files, the hassles of synchronizing the different stores when the data change are removed. [11] Thus WinFS can reduce redundancies. [6] [9]
Access to all the data in the system allows complex searches for data across all the data items managed by WinFS. In the example used above ("the phone numbers of all persons who live in Acapulco and each have more than 100 appearances in my photo collection and with whom I have had e-mail within last month"), WinFS can traverse the subject relationship of all the photos to find the contact items. Similarly, it can filter all emails in last month and access the communicated with relation to reach the contacts. The common contacts can then be figured out from the two sets of results and their phone number retrieved by accessing the suitable property of the contact items.
In addition to fully schematized data (like XML and relational data), WinFS supports semi-structured data (such as images, which have an unstructured bitstream plus structured metadata) as well as unstructured data (such as files) as well. It stores the unstructured components as files while storing the structured metadata in the structured store. [10] Internally, WinFS uses a relational database to manage data. It does not limit the data to belonging to any particular data model. The WinFS runtime maps the schema to a relational modality, [6] by defining the tables it will store the types in and the primary keys and foreign keys that would be required to represent the relationships. WinFS includes mappings for object and XML schemas by default. Mappings for other schemas must be specified. Object schemas are specified in XML; WinFS generates code to surface the schemas as .NET classes. ADO.NET can be used to directly specify the relational schema, though a mapping to the object schema must be provided to surface it as classes. [10] Relationship traversals are performed as joins on these tables. WinFS also automatically creates indexes on these tables, to enable fast access to the information. [10] Indexing speeds up joins significantly, and traversing relationships to retrieve related data is performed very fast. Indexes are also used during information search; searching and querying use the indexes to quickly complete the operations, much like desktop search systems.
This article's factual accuracy may be compromised due to out-of-date information.(February 2019) |
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Timeline of the various structured storage projects by Microsoft. None yet has resulted in a full featured runtime and API around it. Years are approximate. |
The development of WinFS is an extension to a feature that was initially planned in the early 1990s. Dubbed Object File System, it was supposed to be included as part of Cairo. OFS was supposed to have powerful data aggregation features, [12] but the Cairo project was shelved, and with it OFS. However, later during the development of COM, a storage system, called Storage+, based on then-upcoming SQL Server 8.0, was planned, which was slated to offer similar aggregation features. [12] This, too, never materialized, and a similar technology, Relational File System (RFS), was conceived to be launched with SQL Server 2000. [12] However, SQL Server 2000 ended up being a minor upgrade to SQL Server 7.0 and RFS was not implemented.
The concept was not scrapped, and served as the base for WinFS. [12] WinFS was initially planned for inclusion in Windows Vista, [14] and build 4051 of Windows Vista, then called by its codename "Longhorn", given to developers at the Microsoft Professional Developers Conference in 2003, included WinFS, but it suffered from significant performance issues. [12] In August 2004, Microsoft announced that WinFS would not ship with Windows Vista; it would instead be available as a downloadable update after Vista's release. [12]
On August 29, 2005, [12] Microsoft quietly made Beta 1 of WinFS available to MSDN subscribers. It worked on Windows XP, and required the .NET Framework to run. The WinFS API was included in the System.Storage namespace. [15] The beta was refreshed on December 1, 2005 to be compatible with version 2.0 of the .NET Framework. [16] WinFS Beta 2 was planned for some time later in 2006, [17] and was supposed to include integration with Windows Desktop Search, so that search results include results from both regular files and WinFS stores, as well as allow access of WinFS data using ADO.NET. [18]
On June 23, 2006, the WinFS team at Microsoft announced that WinFS would no longer be delivered as a separate product, [4] [19] and some components would be brought under the umbrella of other technologies. Many of the principle features Microsoft intended to provide with WinFS included a pane for metadata property editing, breadcrumb-based property navigation, filtering or stacking items over properties, incremental search, and saved searches; [20] these features were incorporated in Windows Vista. [21] Query composition, a feature of WinFS that allowed users to perform additional searches that reuse the results of a previous query, [22] was later incorporated in Windows Vista. [23]
Examples of uses of the technology are the object-relational mapping components into ADO.NET Entity Framework; support for unstructured data, adminless mode of operation, support for file system objects via the FILESTREAM
data type, and hierarchical data in SQL Server 2008, then codenamed Katmai, as well as integration with Win32 APIs and Windows Shell and support for traversal of hierarchies by traversing relationships into later releases of Microsoft SQL Server; [5] and the synchronization components into Microsoft Sync Framework. [5]
In 2013 Bill Gates cited WinFS as his greatest disappointment at Microsoft and that the idea of WinFS was ahead of its time, which will re-emerge. [24]
WinFS uses a relational engine, which derives from SQL Server 2005, [25] to provide the data-relations mechanism. WinFS stores are simply SQL Server database (.MDF) files with the FILESTREAM attribute set. [26] These files are stored in the access-restricted folder named "System Volume Information" (placed in the volume root), [27] in folders under the folder "WinFS" with names of GUIDs of these stores. [26]
At the bottom of the WinFS stack lies WinFS Core, which interacts with the filesystem and provides file-access and -addressing capabilities. [8] The relational engine leverages the WinFS core services to present a structured store and other services such as locking, which the WinFS runtime uses to implement the functionality. The WinFS runtime exposes services such as Synchronization and Rules that can be used to synchronize WinFS stores or perform certain actions on the occurrence of certain events. [8]
WinFS runs as a service that runs three processes: [28]
It allows programmatic access to its features via a set of .NET Framework APIs. These enable applications to define custom-made data types, define relationships among data, store and retrieve information, and allow advanced searches. [6] [8] The applications can then aggregate the data and present the aggregated data to the user.
WinFS stores data in relational stores, which are exposed as virtual locations called stores. [12] A WinFS store is a common repository where any application can store data along with its metadata, relationships and schema. WinFS runtime can apply certain relationships itself; for example, if the values of the subject property of a picture and the name property of a contact are same, then WinFS can relate the contact with the picture. [29] Relations can also be specified by other applications or the user. [30]
WinFS provides unified storage, but stops short of defining the format that is to be stored in the data stores. Instead it supports writing data in application-specific formats. But applications must provide a schema that defines how the file format should be interpreted. [6] For example, a schema could be added to allow WinFS to understand how to read and thus be able to search and analyze, (say) a PDF file. By using the schema, any application can read data from any other application, and this also allows different applications to write in each other's format by sharing the schema. [30]
Multiple WinFS stores can be created on a single machine. [30] This allows different classes of data to be kept segregated; for example, official documents and personal documents can be kept in different stores. WinFS, by default, provides only one store, named "DefaultStore". [12] WinFS stores are exposed as shell objects, akin to Virtual folders, which dynamically generate a list of all items present in the store and present them in a folder view. The shell object also allows searching information in the datastore. [12]
A data unit that has to be stored in a WinFS store is called a WinFS Item. [6] [30] A WinFS item, along with the core data item, also contains information on how the data item is related to other data. This Relationship is stored in terms of logical links. Links specify which other data items the current item is related with. Put in other words, links specify the relationship of the data with other data items. Links are physically stored using a link identifier, which specifies the name and intent of the relationship, such as type of or consists of. [6] The link identifier is stored as an attribute of the data item. All the objects that have the same link ID are considered to be related. [6] An XML schema, defining the structure of the data items that will be stored in WinFS, must be supplied to the WinFS runtime beforehand. [6] In Beta 1 of WinFS, the schema assembly had to be added to the GAC before it could be used.
WinFS models data using the data items, along with their relationships, extensions and rules governing its usage. [8] WinFS needs to understand the type and structure of the data items, so that the information stored in the data item can be made available to any application that requests it. This is done by the use of schemas. For every type of data item that is to be stored in WinFS, a corresponding schema needs to be provided to define the type, structure and associations of the data. These schemas are defined using XML. [6]
Predefined WinFS schemas include schemas for documents, e-mail, appointments, tasks, media, audio, video, and also includes system schemas that include configuration, programs, and other system-related data. [8] Custom schemas can be defined on a per-application basis, in situations where an application wants to store its data in WinFS, but not share the structure of that data with other applications, or they can be made available across the system. [8]
The most important difference between a file system and WinFS is that WinFS knows the type of each data item that it stores. And the type specifies the properties of the data item. The WinFS type system is closely associated with the .NET framework's concept of classes and inheritance. A new type can be created by extending and nesting any predefined types. [6]
WinFS provides four predefined base types –Items, Relationships, ScalarTypes and NestedTypes. [6] An Item is the fundamental data object which can be stored, and a Relationship is the relation or link between two data items. Since all WinFS items must have a type, the type of item stored defines its properties. The properties of an Item may be a ScalarType, which defines the smallest unit of information a property can have, or a NestedType, which is a collection of more than one ScalarTypes and/or NestedTypes. All WinFS types are made available as .NET CLR classes. [30]
Any object represented as a data unit, such as contact, image, video, document etc., can be stored in a WinFS store as a specialization of the Item type. [30] By default, WinFS provides Item types for Files, Contact, Documents, Pictures, Audio, Video, Calendar, and Messages. The File Item can store any generic data, which is stored in file systems as files. But unless an advanced schema is provided for the file, by defining it to be a specialized Item, WinFS will not be able to access its data. Such a file Item can only support being related to other Items. [6]
A developer can extend any of these types, or the base type Item, to provide a type for their custom data. The data contained in an Item is defined in terms of properties, or fields that hold the actual data. For example, an Item Contact may have a field Name that is a ScalarType, and one field Address, a NestedType, which is further composed of two ScalarTypes. To define this type, the base class Item is extended and the necessary fields are added to the class. [6] A NestedType field can be defined as another class that contains the two ScalarType fields. Once the type is defined, a schema has to be defined, which denotes the primitive type of each field, for example, the Name field is a String, the Address field is a custom defined Address class, both the fields of which are Strings. Other primitive types that WinFS supports are Integer, Byte, Decimal, Float, Double, Boolean and DateTime, among others. [6] The schema will also define which fields are mandatory and which are optional. [31] The Contact Item defined in this way will be used to store information regarding the Contact, by populating the properties field and storing it. Only those fields marked as mandatory needs to be filled up during initial save. [30] Other fields may be populated later by the user, or not populated at all. If more properties fields, such as last conversed date, need to be added, this type can be extended to accommodate them. Item types for other data can be defined similarly.
WinFS creates tables for all defined Items. [31] All the fields defined for the Item form the columns of the table and all instances of the Item are stored as rows in the table for the respective Items. Whenever some field in the table refers to data in some other table, it is considered a relationship. The schema of the relationship specifies which tables are involved and what the kind and name of the relationship is. The WinFS runtime manages the relationship schemas. [30] All Items are exposed as .NET CLR objects, with a uniform interface providing access to the data stored in the fields. Thus any application can retrieve object of any Item type and can use the data in the object, without being aware of the physical structure the data was stored in. [6]
WinFS types are exposed as .NET classes, which can be instantiated as .NET objects. Data are stored in these type instances by setting their properties. Once done, they are persisted into the WinFS store. A WinFS store is accessed using an ItemContext class (see Data retrieval section for details). ItemContext allows transactional access to the WinFS store; i.e. all the operations since binding an ItemContext object to a store till it is closed either all succeed or are all rolled back. As changes are made to the data, they are not written to the disc; rather they are written to an in-memory log. Only when the connection is closed are the changes written to the disc in a batch. This helps to optimize disc I/O. [10] The following code snippet, written in C#, creates a contact and stores it in a WinFS store.
//Connect to the default WinFS storeusing(ItemContextic=ItemContext.Open()){//Create the contact and set the data in appropriate propertiesContactEAddresscontact=newContactEAddress(){Name=newPersonName(){// Name is a ComplexTypeDisplayname="Doe, John",FirstName="John",LastName="Doe"},TelephoneNumber=newTelephoneNumber(){// Telephone number is a ComplexTypeCountry=CountryCode.Antarctica,Areacode=4567,Number=9876543210},Age=111// Age is a SimpleType};//Add the object to the user's personal folder.//This relates the item with the Folder pseudo-type, for backward//compatibility, as this lets the item to be accessed in a folder //hierarchy for apps which are not WinFS native.FoldercontainingFolder=UserDataFolder.FindMyPersonalFolder();containingFolder.OutFolderMemberRelationship.AddItem(ic,contact);//Find a document and relate with the document. Searching begins by creating an//ItemSearcher object. Each WinFS type object contains a GetSearcher() method//that generates an ItemSearcher object which searches documents of that type.using(ItemSearchersearcher=Document.GetSearcher(ic)){Documentd=searcher.Find(@"Title = 'Some Particular Document'");d.OutAuthoringRelationship.AddItem(ic,contact);}//Since only one document is to be found, the ItemContext.FindOne() method//could be used as well.//Find a picture and relate with itusing(ItemSearchersearcher=Picture.GetSearcher(ic)){Picturep=searcher.Find(@"Occasion = 'Graduation' and Sequence = '3'");p.OutSubjectRelationship.AddItem(ic,contact);}//Persist to the store and close the reference to the storeic.Update();}
A datum can be related to one more item, giving rise to a one-to-one relationship, or with more than one items, resulting in a one-to-many relationship. [6] The related items, in turn, may be related to other data items as well, resulting in a network of relationships, which is called a many-to-many relationship. Creating a relationship between two Items creates another field in the data of the Items concerned which refer the row in the other Item's table where the related object is stored. [30]
In WinFS, a Relationship is an instance of the base type Relationship, which is extended to signify a specialization of a relation. A Relationship is a mapping between two items, a Source and a Target. The source has an Outgoing Relationship, whereas the target gets an Incoming Relationship. [31] WinFS provides three types of primitive relationships – Holding Relationship, Reference Relationship and Embedding Relationship. [6] Any custom relationship between two data types are instances of these relationship types.
Relationships between two Items can either be set programmatically by the application creating the data, or the user can use the WinFS Item Browser to manually relate the Items. [31] A WinFS item browser can also graphically display the items and how they are related, to enable the user to know how their data are organized. [30]
WinFS includes Rules, [22] which are executed when a certain condition is met. WinFS rules work on data and data relationships. For example, a rule can be created that states that whenever an Item is created which contains field "Name" and if the value of that field is some particular name, a relationship should be created that relates the Item with some other Item. WinFS rules can also access any external application. For example, a rule can be built which launches a Notify application whenever a mail is received from a particular contact. [22] WinFS rules can also be used to add new properties fields to existing data Items. [22]
WinFS rules are also exposed as .NET CLR objects. As such any rule can be used for any purpose. A rule can even be extended by inheriting from it to form a new rule that consists of the condition and action of the parent rule plus something more. [22]
WinFS supports creating Rich Application Views (RAV) by aggregating different data in a virtual table format. Unlike database view, where each individual element can only be a scalar value, RAVs can have complex Items or even collections of Items. The actual data can be across multiple data types or instances and can even be retrieved by traversing relationships. [10] RAVs are intrinsically paged (dividing the entire set of data into smaller pages containing disconnected subsets of the data) by the WinFS runtime. The page size is defined during creation of the view and the WinFS API exposes methods to iterate over the pages. RAVs also supports modification of the view according to different grouping parameters. Views can also be queried against.
Even though all data are shared, everything is not equally accessible. WinFS uses the Windows authentication system to provide two data protection mechanisms. [30] First, there is share-level security that controls access to your WinFS share. Second, there is item level security that supports NT compatible security descriptors. The process accessing the item must have enough privileges to access it. Also in Vista there is the concept of "integrity level" for an application. Higher integrity data cannot be accessed by a lower integrity process.
The primary mode of data retrieval from a WinFS store is querying the WinFS store according to some criteria, [8] which returns an enumerable set of items matching the criteria. The criteria for the query is specified using the OPath query language. The returned data are made available as instances of the type schemas, conforming to the .NET object model. [32] The data in them can be accessed by accessing the properties of individual objects. [31]
Relations are also exposed as properties. Each WinFS Item has two properties, named IncomingRelationships and OutgoingRelationships, which provide access to the set of relationship instances the item participates in. The other item which participates in one relationship instance can be reached through the proper relationship instance. [10] [31]
The fact that the data can be accessed using its description, rather than location, can be used to provide end-user organizational capabilities without limiting to the hierarchical organization as used in file-systems. In a file system, each file or folder is contained in only one folder. But WinFS Items can participate in any number of holding relationships, that too with any other items. As such, end users are not limited to only file/folder organization. Rather, a contact can become a container for documents; a picture a container for contacts and so on. For legacy compatibility, WinFS includes a pseudo-type called Folder, which is present only to participate in holding relationships and emulate file/folder organization. Since any WinFS Item can be related with more than one Folder item, from an end user perspective, an item can reside in multiple folders without duplicating the actual data. [10] Applications can also analyze the relationship graphs to present various filters. For example, an email application can analyze the related contacts and the relationships of the contacts with restaurant bills and dynamically generate filters like "Emails sent to people I had lunch with".
The WinFS API provides a class called the ItemContext class, which is bound to a WinFS store. The ItemContext object can be used to scope the search to the entire store or a subset of it. It also provides transactional access to the store. [15] An object of this class can then spawn an ItemSearcher object which then takes the type (an object representing the type) of the item to be retrieved or the relationship and the OPath query string representing the criteria for the search. [31] [33] A set of all matches is returned, which can then be bound to a UI widget for displaying en masse or enumerating individually. [30] The properties items can also be modified and then stored back to the data store to update the data. The ItemContext object is closed (which marks the end of association of the object with the store) when the queries are made or changes merged into the store.
Related items can also be accessed through the items. The IncomingRelationships and OutgoingRelationships properties give access to all the set of relationship instances, typed to the name of the relationship. These relationship objects expose the other item via a property. So, for example, if a picture is related to a picture, it can be accessed by traversing the relationship as:
ContactsCollectioncontacts=picture.OutgoingRelationships.Cast(typeof(Contact)).Value;// This retrieves the collection of all outgoing relationships from a picture object// and filters down the contacts reachable from them and retrieves its value.// Or the relationship can be statically specified asContactsCollectioncontacts=picture.OutgoingRelationships.OutContactRelationship.Contact;
An OPath query string allows to express the parameters that will be queried for to be specified using Item properties, embedded Items as well as Relationships .[ citation needed ] It can specify a single search condition, such as "title = Something'", or a compound condition such as "title = 'Title 1' || title = 'Title 2' && author = 'Someone'". These boolean and relational operations can be specified using C# like &&, ||, =, != operators as well as their English-like equivalent like EQUAL, NOT EQUAL. SQL like operators such as LIKE, GROUP BY and ORDER BY are also supported, as are wildcard conditions.[ citation needed ] So, "title LIKE 'any*'" is a valid query string. These operators can be used to execute complex searches such as
using(ItemContextic=ItemContext.Open()){// Searching begins by creating a ItemSearcher object. The searcher is created from a// relationship instance because the contacts being searched for are in relation. The// first parameter defines the scope of the search. An ItemContext as the scope means// the entire store is to be searched. Scope can be limited to a set of Items which may// be in a holding relationship with the contacts. In that case, the set is passed as// the scope of the search.ItemSearchersearcher=OutContactRelationship.GetTargetSearcher(ic,typeof(Contact));ContactCollectioncontacts=searcher.FindAll("OutContactRelationship.Contact.Name LIKE 'A*'");}
The above code snippet creates an ItemSearcher object that searches on the OutContactRelationship instance that relates pictures and contacts, in effect searching all pictures related with a contact. It then runs the query Name LIKE 'A*'" on all contacts reachable through OutContactRelationship, returning the list of "contacts whose names start with A and whose pictures I have". Similarly, more relationships could be taken into account to further narrow down the results. [10] [31] Further, a natural language query processor, which parses query in natural language and creates a well-formed OPath query string to search via proper relationships, can allow users to make searches such as "find the name of the wine I had with person X last month", provided financial management applications are using WinFS to store bills.
Different relations specify a different set of data. So when a search is made that encompasses multiple relations, the different sets of data are retrieved individually and a union of the different sets is computed. The resulting set contains only those data items that correspond to all the relations. [31]
WinFS includes better support for handling data that changes frequently. Using WinFS Notifications, applications choose to be notified of changes to selected data Items. WinFS will raise an ItemChangedEvent, using the .NET Event model, when a subscribed-to Item changes, and the event will be published to the applications. [31]
WinFS includes an Information Agent feature for the management, retrieval, and storage of end-user notification rules and preferences for changes to items in the data store. Using Information Agent, it is possible to automatically define relations to new items based on events such as appointments, with an example being that appointments can be related to photos based on the dates the photos were taken, enabling queries for birthdays or holidays without needing to know the actual dates of such events ("find all photos taken on this birthday"). Other examples include automatically moving new items to specific folders based on a rule as determined by appointment times and dates the photos were taken ("when I import a photo taken during a business event, move it to the Business Events folder") or more complex possibilities. Information Agent can also forward notifications to other devices ("if I receive a high priority email from my boss, send a notification to my phone") and is similar to Rules and Alerts functionality of Microsoft Outlook.
WinFS allows easy sharing of data between applications, and among multiple WinFS stores, which may reside on different computers, by copying to and from them. [34] A WinFS item can also be copied to a non-WinFS file system, but unless that data item is put back into the WinFS store, it will not support the advanced services provided by WinFS.
The WinFS API also provides some support for sharing with non-WinFS applications. WinFS exposes a shell object to access WinFS stores. This object maps WinFS items to a virtual folder hierarchy, and can be accessed by any application. [12] Virtual folders can automatically share new content referenced by the query with users (a virtual folder for "all vacation photos" can automatically share new items returned by this query with users). WinFS data can also be manually shared using network shares, by sharing the legacy shell object. [34] Non-WinFS file formats can be stored in WinFS stores, using the File Item, provided by WinFS. Importers can be written, to convert specific file formats to WinFS Item types. [34]
In addition, WinFS provides services to automatically synchronize items in two or more WinFS stores, subject to some predefined condition, such as "share only photos" or "share photos that have an associated contact X". [34] The stores may be on different computers. Synchronization is done in a peer-to-peer fashion; there is no central authority. A synchronization can be either manual or automatic or scheduled. During synchronization, WinFS finds the new and modified Items, and updates accordingly. If two or more changes conflict, WinFS can either resort to automatic resolution based on predefined rules, or defer the synchronization for manual resolution. WinFS also updates the schemas, if required. [34]
WinFS Beta 1 includes a shell namespace extension, which surfaces WinFS stores as top level objects in My Computer view. [12] Files can be copied into and out of the stores, as well as applications can be directly used to save there. Even folders such as My Documents can be redirected to the stores. [12] WinFS uses Importer plug-ins to analyze the files as they were being imported to the store and create proper WinFS schemas and objects, and when taking the objects out, re-pack them into files. [34] If importers for certain files are not installed, they are stored as generic File types.
Microsoft Rave is an application that shipped with WinFS Beta 1. It allows synchronization of two or more WinFS stores, and supports synchronization in full mesh mode as well as the central hub topology. While synchronizing, Microsoft Rave will determine the changes made to each store since the last sync, and update accordingly. When applying the changes, it also detects if there is any conflict, i.e., the same data has been changed on both stores since the last synchronization. It will either log the conflicting data for later resolution or have it resolved immediately. Microsoft Rave uses peer-to-peer technology to communicate and transfer data.
With WinFS Beta 1, Microsoft included an unsupported application called StoreSpy, [35] which allowed one to browse WinFS stores by presenting a hierarchical view of WinFS Items. It automatically generated virtual folders based on access permissions, date and other metadata, and presented them in a hierarchical tree view, akin to what traditional folders are presented in. The application generated tabs for different Item types. StoreSpy allowed viewing Items, Relationships, MultiSet, Nested Elements, Extensions [36] and other types in the store along with its full metadata. It also presented a search interface to perform manual searches, and save them as virtual folders. The application also presented a graphical view of WinFS Rules. However, it did not allow editing of Items or their properties, though it was slated for inclusion in a future release. [37] But the WinFS project was cut back before it could materialize.
WinFS also includes another application, named WinFS Type Browser, which can be used to browse the WinFS types, as well as visualize the hierarchical relationship between WinFS types. [38] A WinFS type, both built-in types as well as custom schemas, can be visualized along with all the properties and methods that it supports. It also shows the types that it derives from as well as other types that extend the type schema. However, while it was included with WinFS, it was released as an unsupported tool. [38]
WinFS Beta 1 also includes an unsupported application, named OPather. [39] It presents a graphical interface for writing Opath queries. It can be used by selecting target object type and specifying the parameters of the query. It also includes Intellisense-like parameter completion feature. It can then be used to perform visualization tasks like binding results of a query to a DataGrid control, create views of the data in WinFS itself, or just extract the query string.
Microsoft launched a project to build a data visualization application for WinFS. It was codenamed "Project Orange" and was supposedly built using Windows Presentation Foundation. [40] It was supposed to provide exploration of Items stored in WinFS stores, and data relationships were supposed to be a prominent part of the navigation model. It was supposed to let people allow organization of the WinFS stores graphically as well – productizing many of the concepts shown in the IWish Concept Video WMV File. However, since the WinFS project went dark, the status of this project is unknown.
In computing, a database is an organized collection of data or a type of data store based on the use of a database management system (DBMS), the software that interacts with end users, applications, and the database itself to capture and analyze the data. The DBMS additionally encompasses the core facilities provided to administer the database. The sum total of the database, the DBMS and the associated applications can be referred to as a database system. Often the term "database" is also used loosely to refer to any of the DBMS, the database system or an application associated with the database.
Microsoft Access is a database management system (DBMS) from Microsoft that combines the relational Access Database Engine (ACE) with a graphical user interface and software-development tools. It is a member of the Microsoft 365 suite of applications, included in the Professional and higher editions or sold separately.
An object–relational database (ORD), or object–relational database management system (ORDBMS), is a database management system (DBMS) similar to a relational database, but with an object-oriented database model: objects, classes and inheritance are directly supported in database schemas and in the query language. Also, as with pure relational systems, it supports extension of the data model with custom data types and methods.
A data model is an abstract model that organizes elements of data and standardizes how they relate to one another and to the properties of real-world entities. For instance, a data model may specify that the data element representing a car be composed of a number of other elements which, in turn, represent the color and size of the car and define its owner.
File Explorer, previously known as Windows Explorer, is a file manager application and default desktop environment that is included with releases of the Microsoft Windows operating system from Windows 95 onwards. It provides a graphical user interface for accessing the file systems, as well as user interface elements such as the taskbar and desktop.
Database design is the organization of data according to a database model. The designer determines what data must be stored and how the data elements interrelate. With this information, they can begin to fit the data to the database model. A database management system manages the data accordingly.
ADO.NET is a data access technology from the Microsoft .NET Framework that provides communication between relational and non-relational systems through a common set of components. ADO.NET is a set of computer software components that programmers can use to access data and data services from a database. It is a part of the base class library that is included with the Microsoft .NET Framework. It is commonly used by programmers to access and modify data stored in relational database systems, though it can also access data in non-relational data sources. ADO.NET is sometimes considered an evolution of ActiveX Data Objects (ADO) technology, but was changed so extensively that it can be considered an entirely new product.
An XML database is a data persistence software system that allows data to be specified, and sometimes stored, in XML format. This data can be queried, transformed, exported and returned to a calling system. XML databases are a flavor of document-oriented databases which are in turn a category of NoSQL database.
Object–relational impedance mismatch is a set of difficulties going between data in relational data stores and data in domain-driven object models. Relational Database Management Systems (RDBMS) is the standard method for storing data in a dedicated database, while object-oriented (OO) programming is the default method for business-centric design in programming languages. The problem lies in neither relational databases nor OO programming, but in the conceptual difficulty mapping between the two logic models. Both logical models are differently implementable using database servers, programming languages, design patterns, or other technologies. Issues range from application to enterprise scale, whenever stored relational data is used in domain-driven object models, and vice versa. Object-oriented data stores can trade this problem for other implementation difficulties.
In computing, a virtual folder generally denotes an organizing principle for files that is not dependent on location in a hierarchical directory tree. Instead, it consists of software that coalesces results from a data store, which may be a database or a custom index, and presents them visually in the format in which folder views are presented. A virtual folder can be thought of as a view that lists all files tagged with a certain tag, and thus a simulation of a folder whose dynamic contents can be assembled on the fly, when requested. It is related in concept to several other topics in computer science, with names including saved search, saved query, and filtering.
Compared with previous versions of Microsoft Windows, features new to Windows Vista are numerous, covering most aspects of the operating system, including additional management features, new aspects of security and safety, new I/O technologies, new networking features, and new technical features. Windows Vista also removed some others.
An entity–attribute–value model (EAV) is a data model optimized for the space-efficient storage of sparse—or ad-hoc—property or data values, intended for situations where runtime usage patterns are arbitrary, subject to user variation, or otherwise unforeseeable using a fixed design. The use-case targets applications which offer a large or rich system of defined property types, which are in turn appropriate to a wide set of entities, but where typically only a small, specific selection of these are instantiated for a given entity. Therefore, this type of data model relates to the mathematical notion of a sparse matrix. EAV is also known as object–attribute–value model, vertical database model, and open schema.
The Open Packaging Conventions (OPC) is a container-file technology initially created by Microsoft to store a combination of XML and non-XML files that together form a single entity such as an Open XML Paper Specification (OpenXPS) document. OPC-based file formats combine the advantages of leaving the independent file entities embedded in the document intact and resulting in much smaller files compared to normal use of XML.
A database model is a type of data model that determines the logical structure of a database. It fundamentally determines in which manner data can be stored, organized and manipulated. The most popular example of a database model is the relational model, which uses a table-based format.
Entity Framework (EF) is an open source object–relational mapping (ORM) framework for ADO.NET. It was originally shipped as an integral part of .NET Framework, however starting with Entity Framework version 6.0 it has been delivered separately from the .NET Framework.
Microsoft SQL Server is a proprietary relational database management system developed by Microsoft. As a database server, it is a software product with the primary function of storing and retrieving data as requested by other software applications—which may run either on the same computer or on another computer across a network. Microsoft markets at least a dozen different editions of Microsoft SQL Server, aimed at different audiences and for workloads ranging from small single-machine applications to large Internet-facing applications with many concurrent users.
A document-oriented database, or document store, is a computer program and data storage system designed for storing, retrieving and managing document-oriented information, also known as semi-structured data.
Windows Search is a content index and desktop search platform by Microsoft introduced in Windows Vista as a replacement for the previous Indexing Service of Windows 2000, Windows XP, and Windows Server 2003, designed to facilitate local and remote queries for files and non-file items in the Windows Shell and in compatible applications. It was developed after the postponement of WinFS and introduced to Windows several benefits of that platform.
A graph database (GDB) is a database that uses graph structures for semantic queries with nodes, edges, and properties to represent and store data. A key concept of the system is the graph. The graph relates the data items in the store to a collection of nodes and edges, the edges representing the relationships between the nodes. The relationships allow data in the store to be linked together directly and, in many cases, retrieved with one operation. Graph databases hold the relationships between data as a priority. Querying relationships is fast because they are perpetually stored in the database. Relationships can be intuitively visualized using graph databases, making them useful for heavily inter-connected data.
The following is provided as an overview of and topical guide to databases: