Confidential computing is a cloud computing technology that isolates sensitive data in a protected CPU enclave during processing. The contents of the enclave—the data being processed, and the techniques that are used to process it—are accessible only to authorized programming code, and are invisible and unknowable to anything or anyone else, including the cloud provider.
As company leaders rely more and more on public and hybrid cloud services, data privacy in the cloud is imperative. The primary goal of confidential computing is to provide greater assurance to leaders that their data in the cloud is protected and confidential, and to encourage them to move more of their sensitive data and computing workloads to public cloud services.
For years, cloud providers have offered encryption services to help protect data at rest (in storage and databases) and data in transit (moving over a network connection). Confidential computing eliminates the remaining data security vulnerability by protecting data in use — that is, during processing or runtime.
Before it can be processed by an application, data must be unencrypted in memory. This leaves the data vulnerable just before, during and just after processing to memory dumps, root user compromises and other malicious exploits.
Confidential computing solves this problem by leveraging a hardware-based trusted execution environment, or TEE, which is a secure enclave within a CPU. The TEE is secured using embedded encryption keys; embedded attestation mechanisms ensure that the keys are accessible to authorized application code only. If malware or other unauthorized code attempts to access the keys — or if the authorized code is hacked or altered in any way — the TEE denies access to the keys and cancels the computation.
In this way, sensitive data can remain protected in memory until the application tells the TEE to decrypt it for processing. While the data is decrypted and throughout the entire computation process, it is invisible to the operating system (or hypervisor in a virtual machine), to other compute stack resources, and to the cloud provider and its employees.
To protect sensitive data, even while in use — and to extend cloud computing benefits to sensitive workloads. When used together with data encryption at rest and in transit with exclusive control of keys, confidential computing eliminates the single largest barrier to moving sensitive or highly regulated data sets and application workloads from an inflexible, expensive on-premises IT infrastructure to a more flexible and modern public cloud platform.
To protect intellectual property. Confidential computing isn't just for data protection. The TEE can also be used to protect proprietary business logic, analytics functions, machine learning algorithms, or entire applications.
To collaborate securely with partners on new cloud solutions. For example, one company's team can combine its sensitive data with another company's proprietary calculations to create new solutions - without either company sharing any data or intellectual property that it doesn't want to share.
To eliminate concerns when choosing cloud providers. Confidential computing lets a company leader choose the cloud computing services that best meet the organization's technical and business requirements, without worrying about storing and processing customer data, proprietary technology and other sensitive assets. This approach also helps alleviate any additional competitive concerns if the cloud provider also provides competing business services.
To protect data processed at the edge. Edge computing is a distributed computing framework that brings enterprise applications closer to data sources such as IoT devices or local edge servers. When this framework is used as part of distributed cloud patterns, the data and application at edge nodes can be protected with confidential computing.
In 2019, a group of CPU manufacturers, cloud providers and software companies — Alibaba, AMD, Baidu, Fortanix, Google, IBM/Red Hat®, Intel, Microsoft, Oracle, Swisscom, Tencent and VMware — formed the Confidential Computing Consortium (CCC) (link resides outside of ibm.com), under the auspices of The Linux Foundation.
The CCC's goals are to define industry-wide standards for confidential computing and to promote the development of open source confidential computing tools. Two of the Consortium's first open source projects, Open Enclave SDK and Red Hat Enarx, help developers build applications that run with without modification across TEE platforms.
However, some of today's most widely used confidential computing technologies were introduced by member companies before the formation of the Consortium. For example, Intel SGX (Software Guard Extensions) technology, which enables TEEs on the Intel Xeon CPU platform, has been available since 2016; in 2018 IBM made confidential computing capabilities generally available with its IBM Cloud® Hyper Protect Virtual Servers and IBM Cloud® Data Shield products.
IBM has been investing in confidential computing research and technologies for more than a decade, and today offers a range of confidential computing cloud services and related, industry-leading data protection capabilities:
To get started with confidential computing on IBM Cloud, sign up for an IBMid and create your IBM Cloud account.
Get a higher level of commercial privacy assurance. Protect your data at rest, in transit, and in use — with complete authority.
A dedicated key management and cloud hardware security module (HSM) service.
Enable runtime memory encryption for Kubernetes containers, without modifying applications.
1. Based on IBM Hyper Protect Crypto Service, the only public-cloud enabled FIPS 140-2 Level 4-certified Hardware Security Module (HSM). FIPS 140-2 Security Level 4 provides the highest level of security defined in this standard. At this security level, the physical security mechanisms provide a comprehensive envelope of protection around the cryptographic module with the intent of detecting and responding to all unauthorized attempts at physical access.
2. Encryption keys and cryptographic operations are protected with highest level certified HSM -with Hyper Protect Crypto services: FIPS 140-2 Level 4. Clients are issued special IBM smart card HSMs (FIPS 140-2 Level 3) to ensure the root of trust. During a trusted key ceremony, these smart cards collectively generate AES256 bit key parts that are securely transferred to the platform’s HSM and assembled into a master wrapping key inside an isolated HSM (FIPS 140-2 Level 4) domain. Only the client retains control of their master wrapping key. HSM domains are highly isolated and protected by 360-degree envelope tamper detection and response.