The present application describes a system and method for passively collecting DNS traffic data as that data is passed between a recursive DNS resolver and an authoritative DNS server. The information contained in the collected DNS traffic data is used to generate a virtual authoritative DNS server, or a zone associated with the authoritative DNS server, when it is determined that the authoritative DNS server has been compromised.

Systems, methods and devices are provided for registering DNS hostnames of Internet host devices for very large domain zones (VLZ) stored on a DNS server on a network, including setting a pseudo-zone as the VLZ, intercepting DNS updates to the pseudo-zone, mapping the entries in the pseudo-zone into a hierarchy of real parent zones and sub-zones using a mapping formula, and translating DNS updates to the pseudo-zone from an original fully qualified domain name (FQDN) into a at least one new FQDNs and adding the at least one new FQDNs to an authoritative DNS Server.

The present disclosure relates to the field of data processing technology, and more particularly, relates to a method for network traffic forwarding, request sending, and communication acceleration, a forwarding server and a node server. The network traffic forwarding method includes: receiving a first access request carrying an acceleration domain name from a user terminal and determining whether an origin site domain name corresponding to the acceleration domain name exists; if the origin site domain name exists, obtaining the origin site domain name corresponding to the acceleration domain name according to a first pre-set rule; and sending a second access request carrying the origin site domain name and corresponding origin site address information to an Internet acceleration platform to perform an accelerated transmission process in response to the second access request.

The present disclosure relates to the field of data processing technology, and more particularly, relates to a method for network traffic forwarding, request sending, and communication acceleration, a forwarding server and a node server. The network traffic forwarding method includes: receiving a first access request carrying an acceleration domain name from a user terminal and determining whether an origin site domain name corresponding to the acceleration domain name exists; if the origin site domain name exists, obtaining the origin site domain name corresponding to the acceleration domain name according to a first pre-set rule; and sending a second access request carrying the origin site domain name to an Internet acceleration platform. The present disclosure also provides the method for request sending and communication acceleration, the forwarding server, and the node server. As such, no longer limited by the Internet access scenarios, users may enjoy an Internet acceleration service to meet the demand of fast accesses to designated websites in any scenarios. It is a great relief to the users by removing the hardware device deployed on the user side, satisfying the stringent information security requirement, and reducing the cost of the users.

When a Rich Communications Services (RCS) data file is to be provided to a terminating user equipment (UE) that is on a different mobile communications network than an originating UE, the network address, or uniform resource locator (URL), of the RCS data file may be modified to indicate that the RCS data file is to traverse a network-to-network interface (NNI). An RCS system on the originating mobile communications network may identify if the terminating UE is on the same or different mobile communications network. If the terminating UE is on a different mobile communications network, then the RCS system may modify the URL to indicate the originating and terminating mobile communications networks and send the URL to an RCS system of the terminating mobile communications network. The modified URL enables retrieval of the RCS data file network by a content system of the terminating mobile communications network.

The subject technology provides an in-place encoding of a network identifier that compresses the network identifier without mapping the network identifier to a another server or service, such as URL shortening service. The network identifier may be compressed using segmented encoding operations that segment the network identifier, and encode the characters of the network identifier using a first set of encoding operations for a first portion of the network identifier and a second set of encoding operations for a second portion of the network identifier. Template encoding may also be provided for network identifiers that conform to a predefined template format.

The subject technology provides an in-place encoding of a network identifier that compresses the network identifier without mapping the network identifier to a another server or service, such as URL shortening service. The network identifier may be compressed using segmented encoding operations that segment the network identifier, and encode the characters of the network identifier using a first set of encoding operations for a first portion of the network identifier and a second set of encoding operations for a second portion of the network identifier. Template encoding may also be provided for network identifiers that conform to a predefined template format.

A method for processing a cloud service in a cloud system, wherein the cloud system includes a hosted cloud, an allied cloud, and an alliance management apparatus, wherein the hosted cloud includes a first region, the allied cloud includes a second region, the hosted cloud further provides a virtual region for a user, and the virtual region is mapped by the second region on the hosted cloud. The alliance management apparatus enables a user of the hosted cloud to obtain unified experience when the user accesses the first region and the virtual region in the cloud system, for example, unified experience in control interface access, and unified experience in application programming interface (API) access.

Systems, methods and devices are provided for registering DNS hostnames of Internet host devices for very large domain zones (VLZ) stored on a DNS server on a network, including setting a pseudo-zone as the VLZ, intercepting DNS updates to the pseudo-zone, mapping the entries in the pseudo-zone into a hierarchy of real parent zones and sub-zones using a mapping formula, and translating DNS updates to the pseudo-zone from an original fully qualified domain name (FQDN) into a at least one new FQDNs and adding the at least one new FQDNs to an authoritative DNS Server.

Systems, methods and devices are provided for registering DNS hostnames of Internet host devices for very large domain zones (VLZ) stored on a DNS server on a network, including setting a pseudo-zone as the VLZ, intercepting DNS updates to the pseudo-zone, mapping the entries in the pseudo-zone into a hierarchy of real parent zones and sub-zones using a mapping formula, and translating DNS updates to the pseudo-zone from an original fully qualified domain name (FQDN) into a at least one new FQDNs and adding the at least one new FQDNs to an authoritative DNS Server.