Methods, apparatus, systems and articles of manufacture are disclosed for scalable architectures for reference signature matching and updating. An example method for scalable architectures for reference signature matching and updating includes accessing site signatures to be compared to reference signatures from a first group of media sources. Determining if a first reference node is an owner of a first one of the site signatures. Comparing a neighborhood of site signatures including the first site signature to reference signatures in a first subset of reference signatures when the first reference node is the owner of the first site signature, the first subset of references signatures stored in a first memory partition associated with the first reference node. Not comparing site signature to reference signatures when the first reference node is not the owner of the first one of the site signatures.

A server system, based on content of a first file stored on a first client device being modified, automatically receives a copy of the modified first file from a first transfer client, implemented on the first client device, the copy of the modified first file being an updated version of the first file generated from content of the first file being modified. The server system receives, from the first transfer client, first metadata associated with the updated version of the first file, the first metadata being assigned a first priority greater than a second priority assigned to the copy of the modified first file. The server system automatically transfers the first metadata to a second transfer client, implemented on a second client device, before the copy of the modified first file is transferred to the second transfer client to be stored on the second client device.

The present disclosure is directed toward systems and methods that efficiently and effectively generate and utilize collections of content items. For example, systems and methods described herein generate a collection content item including one or more content item references. In one or more embodiments, the collection content item can include content item references for content items located internally or externally, with granular levels of permissions settings and version controls. Additionally, in response to a detected selection of a content item reference, systems and methods described herein generate a rendering of the associated content item that can be viewed regardless of any third party software installed on the viewing client computing device.

Technology is disclosed for detecting, classifying, and/or enforcing policies on social networking activity. The technology can store a content policy, classify content posted to a social network, determine that the classification corresponds to the content policy, and apply an action specified by the content policy to the posted content.

The described technology is generally directed an extension to the IFS domains architecture, referred to herein as filter domains. IFS domains allows tagging of files in a tree-like dataset. Thus, a domain can be defined at the root of the dataset such as the topmost directory under which all files reside. These domains are inherently hierarchichal, path-based entities. Filter domains extends this organization to allow domains to be applied beyond hierarchical tree structures in order to also provide arbitrary grouping of file objects based on any suitable membership condition.

Examples described herein are generally directed towards file share access, and more specifically towards a mechanism to connect file shares at the protocol level in a distributed file server environment. In operation, a first FSVM hosting a first file share may receive a request by a client to access a location in a name space. The first FSVM may determine the location is at a second file share linked to the first file share. The first FSVM may provide access to the second file share to the client. In some examples, the first file share and the second file share may be linked at the directory level.

The present disclosure provides a method for encryption programming, including: selecting an encrypted programming file that matches the programmer from a target folder; loading the selected encrypted programming file; if a current number of times for programming of the programmer is greater than or equal to a maximum number of times for programming, destroying the selected encrypted programming file and ending programming; otherwise, decrypting the selected encrypted programming file; if the current number of times for programming of the programmer is less than an initial number of times for programming, replacing the current number of times for programming of the programmer with the initial number of times for programming, otherwise, re-encrypting the decrypted encrypted programming file and programing the re-encrypted programming file into a target chip. A programmer is further provided.

A backup method is provided for a file system for managing hierarchical storage including one or more storage media on a computer system including one or more computers. Each of the one or more storage media includes a data part which is separated from an index and on which updated information is appended and kept. Each of a plurality of pieces of data within the file system is managed to be migrated to at least any of the one or more storage media. The backup method includes backing up metadata of the plurality of pieces of data migrated within the file system; and backing up the index of each of the one or more storage media to which the plurality of pieces of data have been migrated, substantially at the same time point as the metadata.

A file system manager implemented at a provider network identifies a storage device of a first group of storage devices of a provider network as an initial location of a file system object. Based on an access metric associated with the object, the file system manager initiates a transfer of contents of the object to a second storage device of a different storage device group, without receiving a client request specifying the transfer. In response to an access request received via a file system programmatic interface, contents of the object are provided from the second storage device. Based on a second access metric, the object is transferred back to the first group of storage devices.

File management is enabled for large numbers of files. Example file management includes setting a grouping identifier for a file. The method further includes determining a storage address of a data block of the file, the storage address indicating an extent where the data block is located and an offset. The method further includes setting, in a storage region of the extent corresponding to the grouping identifier, a flag for the data block based on the offset. In this manner, a large number of files in a distributed file system can be managed more efficiently.