Patent ID: 12206652

DETAILED DESCRIPTION

The present disclosure describes a system and method for transmitting a file securely. In particular, the systems and methods disclosed herein describe techniques for encrypting a file, storing the file with a secure file repository, sharing the file with one or more receivers, and transmitting the key to the one or more receivers via a separate communication.

The present disclosure can be implemented in numerous ways, including as a process; an apparatus; a system; a composition of matter; a computer program product embodied on a non-transitory computer readable storage medium; and/or a processor, such as a processor configured to execute instructions stored on and/or provided by a memory coupled to the processor. These implementations, or any other form that the present disclosure may take, may be referred to as techniques. In general, the order of the steps of disclosed processes may be altered within the scope of the present disclosure. Unless stated otherwise, a component such as a processor or a memory described as being configured to perform a task may be implemented as a general component that is temporarily configured to perform the task at a given time or a specific component that is manufactured to perform the task. As used herein, the term ‘processor’ refers to one or more devices, circuits, and/or processing cores configured to process data, such as computer program instructions.

A detailed description of one or more embodiments of the present disclosure is provided below along with accompanying figures that illustrate the principles of the present disclosure. The present disclosure is described in connection with such embodiments, but the present disclosure is not limited to any embodiment. The scope of the present disclosure is limited only by the claims and the present disclosure encompasses numerous alternatives, modifications, and equivalents. Numerous specific details are set forth in the following description in order to provide a thorough understanding of the present disclosure. These details are provided for the purpose of example and the present disclosure may be practiced according to the claims without some or all of these specific details. For the purpose of clarity, technical material that is known in the technical fields related to the present disclosure has not been described in detail so that the present disclosure is not unnecessarily obscured.

FIG.1illustrates an embodiment of an environment in which secure communications are exchanged. In particular,FIG.1illustrates a first client device210, a second client device220, and a third client device230connected to security platform120, located on server100, via network112. Additionally,FIG.1illustrates a secure file repository150accessible by the first client device210, second client device220, third client device230, and security platform120through network112.

According to the embodiments described herein, secure communications are exchanged using secure communication containers, which encapsulate a sender's communication. The secure communication container also allows information such as encryption information, hardware binding information, message security controls, and decryption information—for multiple receivers (as applicable)—to securely travel with the message. The secure communication container also provides cross-platform support so that users may communicate regardless of their operating systems (e.g., Linux, iOS, and Windows), smart phone platforms (e.g., iPhone, Android, Windows, Blackberry, etc.), and device types (e.g., mobile smart phones, tablets, laptops, desktops, etc.). Using the techniques described herein, only intended accounts on intended devices are able to decrypt the communications. Thus, for example, the security platform120is unable to decrypt communications. As will further be described in more detail below, using the techniques described herein, communicants can maintain a forward secret secure messaging channel, whether communicating synchronously (e.g., where all communicants are online or otherwise able to communicate with platform120) or asynchronously (e.g., where at least one communicant is offline or otherwise not in communication with platform120).

As shown inFIG.1, security platform120may be implemented on server100. Server100may include a processor102, memory104, user directory106, and the security platform120. In this regard, server100may be a stand-alone server, a corporate server, or a server located in a server farm or cloud-computing environment. In some embodiments, the server100may be a cloud service provider running a virtual machine configured to provide security platform120to an enterprise in the context of Software as a Service (Saas).

Processor102may be any processor capable of interacting with memory104, user directory106, and security platform120. In this regard, processor102may include a processor, multiprocessors, a multicore processor, or any combination thereof. Alternatively, processor102may be a dedicated controller, such as an Application Specific Integrated Circuit (ASIC) or Field Programmable Gate Array (FPGA). As will be described in more detail below, processor102may perform a plurality of tasks on behalf of security platform120. Furthermore, whenever platform120is described as performing a task, either a single component or a subset of components or all components of platform120or enterprise server100may cooperate to perform the task. For example, platform120may generate and assign a random file name to files uploaded to the secure file repository.

Memory104stores information accessible by processor102, including instructions and data that may be executed or otherwise used by the processor102. Memory104may be any type of media capable of storing information accessible by the processor, including a non-transitory computer-readable medium or any other suitable medium that stores data that may be read with the aid of an electronic device, such as a hard-drive, solid state drive, memory card, flash drive, ROM, RAM, DVD, or other optical disks, as well as other write-capable and read-only memories. Memory104may include short term or temporary storage as well as long term or persistent storage. According to some embodiments, memory104may include a storage area network (SAN) accessible by the security platform120.

User directory106may be any database or table capable of providing directory services. For example, user directory may include a corporate directory that include employees' first and last names, usernames, email address, phone numbers, department information, etc. Alternatively, user directory106may be a database or table to maintain user information for users of security platform120. In this regard, user directory106may be encrypted. In some embodiments, user directory106may serve as a secure directory that includes a table of hashed usernames, a table of appIDs, and a table of deviceIDs for a secure messaging app. Accordingly, user directory106may be used to share information about users, systems, networks, services and applications. According to some embodiments, the user directory106may include a Lightweight Directory Access Protocol (LDAP).

AlthoughFIG.1illustrates processor102, memory104, user directory106, and security platform120as being located on server100, processor102and memory104may comprise multiple processors and memories that may or may not be stored within the same physical housing. For example, memory104may be a hard drive or other storage media located in a storage array of a data center. Accordingly, references to a processor, a computer, or a memory will be understood to include references to a collection of processors or computers or memories that may or may not operate in parallel. Further, the user directory106may be located in a separate physical housing from processing engine102and memory104. Moreover, security platform120may be distributed across multiple servers.

Security platform120may be configured to facilitate the exchange of communications for users of a secure collaboration app. As used herein, “communications” and “messages” may take a variety of forms, including: text messages, chat room messages, file sharing, file collaboration, control messages, commands, e-mails, documents, audiovisual files, Short Message Service messages (SMSes), voice calls (i.e., VOIP), video calls, and video conferences. Additionally, the content of the messages and/or communications may pertain to electronic transactions, such as credit card security, password protection, directories, and storage drive protection, video on demand security, online gaming, gambling, electronic distribution of music, videos, documents, online learning systems, databases, cloud storage and cloud environments, bank transactions, voting processes, military communications, security of medical records, communication between medically implanted devices and doctors, etc. The exchange of messages and/or communications is explained in further detail below.

Security platform120may provide encrypted communications that easily integrate into and secure existing systems while also providing compliant and secure communications. In this regard, security platform120may integrate with existing identity systems, such as user directory106. Further, security platform120may include built-in support for enterprise data retention and support systems.

Security platform120may also include database130. Database130may be a relational database that stores information in a variety of tables. In this regard, database130may include a record for each user of platform120to allow users to find other users and communicate with other users. Accordingly, database130may include a table of hashed usernames132, a table of public keys and reference values134, a table of appIDs136, and a table of deviceIDs138. Each user record may include a hashed username in table132, a pool of ECDH public components and associated reference values in table134, app ID(s) in table136, and deviceID(s) in table138. Additionally, each user record may store privacy mode and privacy list entries to control with whom the user may communicate. Additionally, database130may include a table of communications140. That is, the security platform may store communications for users for a predetermined time in table140. For example, when a message is received, the security platform may store the message in the table of communications and provide an alert, such as a push notification, to the receiver. Accordingly, a receiver may access the security platform to obtain his or her communications stored in table140. In preferred embodiments, table140may store communications for 30 days; however, this may be adjusted, as needed, based on industry standards and/or to comply with regulatory schemes.

While a database is shown inFIG.1, other techniques can be used to store the information used by platform120to facilitate exchange of communications. For example, the table of communications may be stored in a separate storage, such as memory104, instead of being stored within database130. Alternatively, the information contained in the database may be divided between database130and user directory106. In this regard, database130and user directory106may interface to exchange information. Further, additional information can be securely stored on platform120, whether in database130or another appropriate location, such as user verification information and user verification settings.

Security platform120may include one or more interface(s)122for communicating with client devices210,220, and230. As one example, platform120may provide an application programming interface (API) configured to communicate with apps installed on client devices. Further, platform120may also include APIs for interacting with the secure file repository150. Additionally, platform120may provide other types of interfaces, such as a web interface, or stand alone software programs for desktops and laptops, running on various Operating Systems (OSes). The web interface may allow users of client devices to exchange communications securely (whether with one another or other users), without the need for a separately installed collaboration application. The standalone software program may allow users to exchange secure communications via software that is downloaded by each user. According to some embodiments, platform120may make available a master clock time available via the one or more interface(s)122. The master clock time may be used by client apps to enforce secure time-to-live (TTL) values of communications. The TTL values can be used to enforce (e.g., on behalf of a sender) time constraints on communication access (e.g., by a receiver).

Users of client devices, such as client devices210,220,230, may communicate securely with one another using the techniques described herein. For example, client devices210,220,230may make use of the security platform120and the techniques described herein via a secure collaboration app (not shown). As shown inFIG.1, client devices may be mobile devices, such as a laptop, smart phone, or tablet, or computing devices, such as desktop computers or servers. As noted above, the secure collaboration app described herein allows cross-platform communications, thereby allowing users of various devices to communicate seamlessly. Further, each user may have different instances of the collaboration app across multiple devices. That is, the user of device210may be able to receive communications on both device210, as well as on any other devices that the user may have that includes a copy of the secure collaboration app, such as a laptop. In some embodiments, client devices210,220,230may be the users' personal devices (i.e., a bring your own device (BYOD) scenario). Alternatively, client devices may include other types of devices, such as game consoles, camera/video recorders, video players (e.g., incorporating DVD, Blu-ray, Red Laser, Optical, and/or streaming technologies), smart TVs, and other network-connected appliances, as applicable.

Communications between users of client devices210,220,230may be exchanged via network112. Network112may include various configurations and use various protocols including the Internet, World Wide Web, intranets, virtual private networks, local Ethernet networks, private networks using communication protocols proprietary to one or more companies, cellular and wireless networks (e.g., WiFi), instant messaging, HTTP and SMTP, and various combinations of the foregoing.

Additionally, client devices210,220,230may also access the secure file repository150via network112. In preferred embodiments, the secure file repository includes a file management system that is hosted and maintained by the security platform120. In alternative embodiments, the secure file repository may be a third-party file management system, such as Dropbox, Box, Google Drive, etc. According to the alternative embodiments, the secure collaboration apps located on client devices210,220,230may include interfaces, such as APIs, to access the secure file repository150.

The secure file repository150includes a processor152and a memory154, which are similar to the processor102and memory104previously discussed. Additionally, memory154may support a file management system (not shown). In this regard, users may upload content, such as files, documents, spreadsheets, images, animated gifs, videos, etc., to the secure file repository150using the secure collaboration apps located on their client devices. In this regard, the secure collaboration app allows clients to encrypt the files before uploading them to the secure file repository. In this regard, clients may use the secure file repository to store information in a secure manner (e.g., encrypted) for later retrieval. Alternatively, clients may use the secure file repository to transfer information to other users of the secure collaboration app.

FIG.2illustrates an exemplary client device200that may access the security platform120via a secure collaboration app. In this regard, client device200includes a processor202, a memory204, a display206, an I/O unit208, a cryptographic (“crypto”) accelerator212, and a network interface214all interconnected by bus216.

Processor202may be any processor capable of interacting with the components of client device200. For example, processor202may include a processor, multiprocessors, multicore processor, a dedicated controller, such as an ARM processor, an ASIC, or an FPGA, or any combination thereof. Memory204may store information accessible by processor202, including instructions and data that may be executed or otherwise used by the processor202and/or crypto accelerator212. For example, memory204may store instructions, such as app224. In preferred embodiments, app224may be a secure collaboration app that provides users with the ability to participate in voice and video calls, share encrypted content, and exchange encrypted communications. Encrypted communications may include direct communications (e.g., one-to-one communications between a sender and receiver), group chats, or secure chat room communications. Data stored by memory204may include database234. Database234may be encrypted via an encryption algorithm, such as Advanced Encryption Standard (AES), and a 256-bit key, referred to hereinafter as a local storage key. In some embodiments, database234may be used to store information related to secure collaboration app224. For example, database234may index information related to the secure collaboration app, such as key information, user information, friend information, and communications. In this regard, communications transmitted and received by the secure collaboration app, including a message identifier, a hash of the sender's username, a hash of the sender's appID, a hash of the receiver's username, a hash of the receiver's appID, the message encryption key, and a timestamp of each communication may be stored in database234. Accordingly, memory204may be any type of media capable of storing the information above, including a non-transitory computer-readable medium or any other suitable medium that stores data that may be read with the aid of an electronic device, such as a hard-drive, solid state drive, memory card, flash drive, ROM, RAM, DVD, or other optical disks, as well as other write-capable and read-only memories. Further, memory204may include short term or temporary storage as well as long term or persistent storage.

Display206may be any electronic device capable of visually presenting information. In mobile devices, such as smart phones and tablets, display206may be a touchscreen display. In this regard, display206may be integrated with I/O unit208to detect user inputs, as well as output data. In computing devices, display206may be an output, such as a VGA, DVI, or HDMI output, configured to connect to a monitor. I/O unit208may be capable of receiving input from a user. As noted above, the I/O unit208may work with touchscreen displays to receive input from a user. Alternatively, the I/O unit may be an interface capable of interacting with input and output devices, such as keyboards, mice, monitors, printers, etc. Additionally, the I/O unit208may include at least one accelerometer, a Global Positioning Satellite (GPS) system, a magnetometer, a proximity sensor, an ambient light sensory, a moisture sensor, a gyroscope, etc. to determine the orientation of the device, as well as environmental factors.

Crypto accelerator212may be dedicated hardware, software, or any combination thereof that is capable of performing cryptographic operations, such as key generation, random number generation, encryption/decryption, signature generation, signature verification, etc. In preferred embodiments, crypto accelerator212is a dedicated processor configured to perform cryptographic operations on behalf of processor202. In this regard, app224may make use of crypto accelerator212to provide the secure communication functions described in greater detail below.

Network interface214may be dedicated hardware, software, or any combination thereof that is capable of connecting client device200to network112. In this regard, network interface214may include various configurations and use various communication protocols including Ethernet, TCP/IP, ATM, cellular and wireless communication protocols (e.g., 802.11, LTE), instant messaging, HTTP and SMTP, and various combinations of the foregoing.

FIGS.3A and3Billustrate an example of an interface300for exchanging cryptographic communications and securely transferring files. The interface300includes user information field305, which displays user information including the user's name, their username, and an avatar that is displayed to other users. As shown inFIGS.3A and3B, the interface300belongs to Alice Adams. Additionally, the interface300may include a room identification field310and a message identifier field320. The room identification field310and a message identifier field315may indicate the secure chat rooms the user is participating in and the open one-to-one communications the user has open, respectively.

FIGS.3A and3Billustrate that Alice Adams is participating in a secure chat room. This is reflected by the highlighted field (e.g., “Grifted Gobstopper”) under the room identification field310. Additionally, a header330shows general information about the communication that the user is participating in. For example, the header330may include the name of the secure chat room or one-to-one communication, a TTL for all communications, the members of the secure chat room, and a search field. Below the header, a conversation field335is shown. The conversation field335may include the communications, including messages, shared images, videos, voice recordings, etc., exchanged between users. Below the conversation field is a user input field340. The user input field340allows a user to enter text and send the text to other communicants. Additionally, the user input field340may include an upload button345, which allows clients to share content in a secure manner. In particular, clients may select the upload button345which may prompt the client to select a file from their device. Alternatively, selecting the upload button345may prompt the client to take a picture, which will then be uploaded and displayed in the conversation field335. In this regard, any selected files will be encrypted before being shared with other communicants, as discussed in greater detail below.

Turning toFIG.3B, an example of a secure file shared with a communicant is shown. Specifically, image350appears in conversation field335. Image350may be subject to the same constraints as other communications. For example, if there were a TTL set for communications, the image350would be removed from the conversation field upon expiration of the TTL. Furthermore, additional constraints may be put on shared content. For instance, recipients may not be able to screen shot, forward, download, or otherwise share the received file.

As noted above, the secure collaboration app allows clients to securely transfer files with other clients.FIG.4illustrates a process400for securely transferring files. Process400begins in block405, where the secure collaboration app obtains a first file to share with one or more receivers. The first file may be obtained locally from the client's device and include documents, spreadsheets, presentations, images, animated gifs, videos, etc. Alternatively, obtaining a first file may include activating the client device's camera and capturing a new image or video. In other embodiments, obtaining a first file may include activating a microphone and recording a voice recording for transmission to the one or more receivers. In still further embodiments, obtaining the first file may include accessing a secure file repository, using an API provided via the secure collaboration app, to select a stored file.

After the first file is obtained, the secure collaboration app generates a first encryption key in block410. In preferred embodiments, the first encryption key is a 256-bit key generated by the secure collaboration app by applying multiple rounds of a hash function (e.g., SHA256, SHA384, SHA512) to a first set of pseudorandom bytes derived from a sending client's device. The first set of pseudorandom bytes may be derived from ephemeral environmental noise obtained from device drivers and other kernel operations. For example, data from the various sensors (e.g., the at least one accelerometer, Global Positioning Satellite (GPS) system, magnetometer, proximity sensor, ambient light sensor, moisture sensor, and gyroscope) may be used as the first set of pseudorandom bytes.

In block415, the secure collaboration app generates a random file name for the first file. In preferred embodiments, the random file name is a 128-bit universally unique identifier that is generated in accordance with RFC4122: A Universally Unique Identifier (UUID) URN Namespace, the entirety of which is herein incorporated by reference. Next, in block420, the secure collaboration app encrypts the first file using the first encryption key. Preferably, the secure collaboration app on the sending client's device relies on the crypto processor to encrypt the first file using a symmetric encryption algorithm, such as Advanced Encryption Standard (AES), Data Encryption Standard (DES), or Triple DES (3DES). Once the first file is encrypted, the secure collaboration app assigns the random file name to the first encrypted file in block425.

In block430, the secure collaboration app uploads the first encrypted file to the secure file repository. In preferred embodiments, the secure file repository is part of the security platform120. In alternative embodiments, the secure file repository may be operated by a third-party, such as Dropbox, Box, or Google Drive. In block435, the sending client's secure collaboration app receives a location of the first encrypted file from the secure file repository.

In block440, the sending client's secure collaboration app updates metadata associated with the first encrypted file. Specifically, the secure collaboration app will update the name of the file, as well as the location of the first encrypted file in the secure file repository. Further, the secure collaboration app will add the first encryption key to the metadata, for example, as a property of the file. In this regard, the sending client's secure collaboration app maintains a record of the first encrypted file. This record may be stored in database234in the sending client device's memory204. In embodiments where the client device is merely storing the first encrypted file with a secure file repository, the process400ends here. However, if the client device is sharing the first encrypted file with one or more receivers, process400proceeds to block445where the sending client's secure collaboration app generates a second encryption key. Similar to the first encryption key, the second encryption key is a 256-bit key derived by applying multiple rounds of a hash function to a second set of pseudorandom bytes derived from the sending client's device.

In block450, the sender's secure collaboration app encrypts the first encrypted file's metadata, including the first encryption key, using the second encryption key. In some embodiments, the first encrypted file's metadata is encrypted using a symmetric encryption algorithm. The encrypted metadata is then transmitted to one or more receivers in block455.

Turning toFIG.5, a detailed process for transmitting encrypted communications, including the encrypted metadata, to one or more receivers is illustrated. The method begins in block505, with the sending client's secure collaboration app obtaining the one or more receivers' public information from the security platform. In this regard, each receiver's public information may include at least one of the receiver's app ID, user-level signing public key, signed app-level signing public key, a signed ephemeral ECDH public component, an identifier of the ephemeral ECDH public component, and the receiver's device key. In preferred embodiments, the security platform randomly selects one of the signed ephemeral ECDH public components from a pool of public components that the receiver has previously uploaded. In order to prevent the selected public component from being used for a subsequent communication, the security platform will delete the selected ephemeral ECDH public component after providing it to the sending client's device. If a receiver has multiple instantiations of the secure collaboration app installed on different devices, the sender's secure collaboration app will receive a unique signed app-level signing public key, signed ephemeral ECDH public component, identifier of the ephemeral ECDH public component, and device key for each instance of app in block505. The multiple instance information may be provided in an arrayed response by the security platform.

In block510, the sender's secure collaboration app authenticates the public information received from the security platform. In particular, the user-level signing public key received from security platform is used to verify a signature attached to the app-level signing public key. If the receiver has multiple instances of the app, the sender's secure collaboration app will authenticate the app-level public key for each of the receiver's instantiation of the secure collaboration apps. When the signature attached to the app-level public key is successfully validated, the sender's secure collaboration app uses the received app-level signing public key to validate the signatures appended to the received ephemeral ECDH public component.

After authenticating the one or more receivers' public information, the sender composes his or her communication to the one or more receivers in block515. As noted above, the communication may be a text message, chat room message, file sharing, file collaboration, control message, command, e-mail, document, audiovisual file, Short Message Service message (SMSes), voice call (i.e., VOIP), video call, and video conference. Continuing the example described above with respect toFIG.4, the message providing the metadata to the one or more receivers is a control message that notifies the one or more receivers' secure collaboration apps that the sender is sharing a file with the one or more receivers. The payload of the control message will include the metadata of the first encrypted file.

While the sender's secure collaboration app is composing the communication to the one or more receivers, the sender's secure collaboration app generates the second encryption key in block520. As noted above, the sending client's secure collaboration app may use the crypto accelerator to generate the second encryption key by applying multiple rounds of a hash function (e.g., SHA256, SHA384, SHA521) to a second set of pseudorandom bytes. Once the communication is composed and the second encryption key is generated, the sender's secure collaboration app will encrypt the communication in block525. The secure collaboration app encrypts the communication using a symmetric encryption algorithm. Continuing the example above, the sender's secure collaboration app encrypts the metadata, via AES, using the second encryption key.

In block530, the sending client's secure collaboration app generates a pair of ephemeral ECDH components. The pair of ephemeral ECDH components is generated using ECC with a P-521 curve. In block535, the sending client's secure collaboration app derives a key-encrypting key using the receiver's ephemeral ECDH public component and the ephemeral ECDH private component generated by the sending client's secure collaboration app. In preferred embodiments, the key-encrypting key is a 256-bit key derived using ECDH.

In block540, the second encryption key is encrypted using the key-encrypting key. In preferred embodiments, the second encryption key is encrypted by the crypto accelerator using AES and the key-encrypting key. In block545, the sending client's secure collaboration app encrypts the second encryption key again using the receiver's device key obtained from the security platform with the receiver's public information. Encrypting the second encryption key with an ephemeral component generated by the receiver's app and the device key provides a twice-encrypted second encryption key that effectively binds the message to the receiver's secure collaboration app and device.

In block550, the sending client's secure collaboration app determines whether the receiver has multiple instantiations of the secure collaboration app installed on a plurality of devices. If so, the sender's app repeats blocks535,540, and545for each instance of the receiver's app. In this regard, each instance will receive a twice-encrypted second encryption key that is unique to that instantiation of the secure collaboration app. Accordingly, each instance will only be able to decrypt the twice-encrypted second encryption key that has been encrypted with the unique device key and ephemeral public component associated with that device.

When twice-encrypted second encryption keys have been generated for each of the receiver's instantiations of the secure collaboration app, the sending client's secure collaboration app composes a secure communication container in block555. The secure communication container includes a payload and a header. The payload comprises the encrypted communication; while the header of the secure communication container includes destination entries for each of one or more receivers' instantiations of the secure collaboration app. Each destination entry includes at least one of a twice-encrypted second encryption key; an identifier for the ephemeral ECDH component used to generate the key-encrypting key; and the sender's public ECDH component for the key-encrypting key. Following the example above, the payload of the secure communication container will contain the first encrypted file's encrypted metadata.

Once the secure communication container is assembled, the sending client's secure collaboration app will transmit the secure communication container to the one or more receivers in block560. In preferred embodiments, the sending client's secure collaboration app transmits the secure communication container to the security platform. Accordingly, the security platform will notify each of the one or more receivers that they have a new communication waiting for them. Alternatively, the sender and receiver may communicate in a peer-to-peer manner. According to these embodiments, the sending client's secure collaboration app transmits the secure communication container directly to each of the one or more receivers in block560.

Turning toFIG.6, a process illustrating how the secure file repository handles encrypted files is shown. The process600begins in block610with the secure file repository receiving the first encrypted file from the sending client's device. According to preferred embodiments, the first encrypted file is received over a secure channel, such as a channel secured by either the Secure Socket Layer (SSL) or Transport Layer Security (TLS) protocols. In block620, the secure file repository provides the uploading client with a location of the first encrypted file in the secure file repository. The location information allows the uploading client to recover the first encrypted file. Additionally, the location information can be shared with other client devices so that they too can access the first encrypted file. In block630, the secure file repository receives one or more requests for the first encrypted file from one or more receiving client devices. Typically, the requests received from the one or more receiving clients will include at least the random file name and the location of the first encrypted file. In response to receiving the request from one or more receiving clients, the secure file repository transmits the first encrypted file to the one or more receiving client devices in block640. In preferred embodiments, the secure file repository transmits the first encrypted file via a secure channel to the one or more receiving client devices.

Prior to retrieving the first encrypted file from the secure file repository, the one or more receiving client devices must receive notification that a sending client is sharing a file with them.FIG.7illustrates an exemplary process700for receiving notification that a sender is securely transferring a file. In block710, the one or more receiving client devices receive a secure communication container. The secure communication container may contain a communication or a control message. In examples where the secure communication container includes a communication, the receiving client device may receive an alert, such as a push notification, which prompts the receiving client device's secure collaboration app to connect to the security platform and retrieve the sender's secure communication container. In examples where the secure communication container includes a control message, the secure communication container may be pushed directly to the receiving client's device, which prompts the receiving client device's secure collaboration app to decrypt the received control message using the steps described below and execute the command or instruction contained in the payload of the secure communication container.

As noted above, the header of the secure communication container includes a destination entry that includes at least a twice-encrypted second encryption key. Accordingly, in block720, the receiving client device's secure collaboration app decrypts the twice-encrypted second encryption key using the device key associated with the receiving client device. Next, in block730, the receiving client's secure collaboration app uses the ECDH component identifier received in the secure communication container to retrieve the ephemeral ECDH private component that corresponds to the public component the sending client device used to generate the key-encrypting key. In block740, the receiving client's secure collaboration app derives the key-encrypting key using the retrieved ephemeral private component and the sender's ephemeral public component that was transmitted in the secure communication container. After deriving the key-encrypting key, the receiving client device's secure collaboration app decrypts the encrypted second encryption key in block750to obtain the second encryption key. In block760, the second encryption key is used to decrypt the payload of the secure communication container. In preferred embodiments, the payload is decrypted via a symmetric encryption/decryption scheme, such as AES, DES, or 3DES. In examples where the payload contains a communication-such as a message, the decrypted communication may be provided to the receiver in block770. In examples where the payload contains a control message, the receiving client's secure collaboration app May execute the command or instruction contained in the control message. In this regard, the secure collaboration app may display an indication regarding the command executed. For example, if the control message contains information about retrieving a file, an icon may be displayed to the user prompting them to download the file. Alternatively, the file may be retrieved by the secure collaboration app automatically and provide a notification to the user that a file is being shared by the sender.

FIG.8illustrates an exemplary process800of a receiving client's secure collaboration app retrieving and decrypting the first encrypted file. The process800begins in block810when one or more of the receiving clients' secure collaboration apps receive a first encrypted communication from a sender's device. In preferred embodiments, the first encrypted communication is a secure communication container; the payload of which includes the first encrypted file's encrypted metadata. As noted above, the first encrypted file's metadata comprises at least the first encryption key, the random file name assigned to the first encrypted file, and the location of the first encrypted file on the secure file repository. In block820, the receiving client's secure collaboration app decrypts the secure communication container using the process described above inFIG.7. Specifically, the receiving client's secure collaboration app obtains the second encryption key using the techniques described above and uses it to decrypted the payload of the secure communication container to obtain the first encrypted file's metadata. In this regard, the security platform ensures that only intended receivers can access the file on their respective devices, thereby preventing unauthorized users from accessing the file even if they were to receive notification of the secure file transfer inadvertently.

After decrypting the payload of the first encrypted communication and retrieving the first encrypted file's metadata, the receiving client's secure collaboration app retrieves the first encrypted file from the secure file repository in block830. Specifically, the receiving client device's secure collaboration app uses the random file name and the location information contained in the metadata to obtain the first encrypted file from the secure file repository. In various embodiments, the first encrypted file is transferred from the secure file repository to the receiving client device via a secure channel. After receiving the first encrypted file from the secure file repository, the receiving client's secure collaboration app decrypts the first encrypted file using the first encryption key contained in the decrypted metadata in block840. In block850, the decrypted first file is provided to the user for review.

While the above-described embodiments describe sharing one file with one or more receivers, the above-described techniques may apply to the sharing of multiple files. In this regard, each a unique encryption key would be generated for each file. Accordingly, the metadata for each file may be encrypted using the techniques described above. The metadata for each file may then be transmitted in one secure communication container or several secure communication containers.

Although the foregoing embodiments have been described in some detail for purposes of clarity of understanding, the present disclosure is not limited to the details provided. There are many alternative ways of implementing the present disclosure. The disclosed embodiments are illustrative and not restrictive.