Tag Archives: encryption

Podcast: How AWS KMS could help customers meet encryption and deletion requirements, including GDPR

Post Syndicated from Katie Doptis original https://aws.amazon.com/blogs/security/podcast-how-aws-kms-could-help-customers-meet-encryption-and-deletion-requirements-including-gdpr/

Encryption is a powerful tool to protect your data but it can be difficult to get right because it demands understanding how encryption keys are created, distributed, used, and managed. To make encryption easier to use, we created AWS Key Management Service (KMS) to let you scale your use of the cloud without struggling to ensure encryption is used consistently across workloads.

Because AWS KMS makes it easy for you to create and control the encryption keys used to encrypt your data, the service can be used to meet both encryption and deletion requirements in a data lifecycle management policy. Cryptographic deletion is the idea is that you can delete a relatively small number of keys to make a large amount of encrypted data irretrievable. This concept is being widely discussed as an option for organizations facing data deletion requirements, such as those in the EU’s General Data Protection Regulation (GDPR).

Listen to the podcast and hear from Ken Beer, general manager of AWS KMS, about best practices related to encryption, key management, and cryptographic deletion. He also covers the advantages of KMS over on-premises systems and how the service has been designed so that even AWS operators can’t access customer keys.

EC2 Instance Update – M5 Instances with Local NVMe Storage (M5d)

Post Syndicated from Jeff Barr original https://aws.amazon.com/blogs/aws/ec2-instance-update-m5-instances-with-local-nvme-storage-m5d/

Earlier this month we launched the C5 Instances with Local NVMe Storage and I told you that we would be doing the same for additional instance types in the near future!

Today we are introducing M5 instances equipped with local NVMe storage. Available for immediate use in 5 regions, these instances are a great fit for workloads that require a balance of compute and memory resources. Here are the specs:

Instance Name vCPUs RAM Local Storage EBS-Optimized Bandwidth Network Bandwidth
m5d.large 2 8 GiB 1 x 75 GB NVMe SSD Up to 2.120 Gbps Up to 10 Gbps
m5d.xlarge 4 16 GiB 1 x 150 GB NVMe SSD Up to 2.120 Gbps Up to 10 Gbps
m5d.2xlarge 8 32 GiB 1 x 300 GB NVMe SSD Up to 2.120 Gbps Up to 10 Gbps
m5d.4xlarge 16 64 GiB 1 x 600 GB NVMe SSD 2.210 Gbps Up to 10 Gbps
m5d.12xlarge 48 192 GiB 2 x 900 GB NVMe SSD 5.0 Gbps 10 Gbps
m5d.24xlarge 96 384 GiB 4 x 900 GB NVMe SSD 10.0 Gbps 25 Gbps

The M5d instances are powered by Custom Intel® Xeon® Platinum 8175M series processors running at 2.5 GHz, including support for AVX-512.

You can use any AMI that includes drivers for the Elastic Network Adapter (ENA) and NVMe; this includes the latest Amazon Linux, Microsoft Windows (Server 2008 R2, Server 2012, Server 2012 R2 and Server 2016), Ubuntu, RHEL, SUSE, and CentOS AMIs.

Here are a couple of things to keep in mind about the local NVMe storage on the M5d instances:

Naming – You don’t have to specify a block device mapping in your AMI or during the instance launch; the local storage will show up as one or more devices (/dev/nvme*1 on Linux) after the guest operating system has booted.

Encryption – Each local NVMe device is hardware encrypted using the XTS-AES-256 block cipher and a unique key. Each key is destroyed when the instance is stopped or terminated.

Lifetime – Local NVMe devices have the same lifetime as the instance they are attached to, and do not stick around after the instance has been stopped or terminated.

Available Now
M5d instances are available in On-Demand, Reserved Instance, and Spot form in the US East (N. Virginia), US West (Oregon), EU (Ireland), US East (Ohio), and Canada (Central) Regions. Prices vary by Region, and are just a bit higher than for the equivalent M5 instances.

Jeff;

 

E-Mail Vulnerabilities and Disclosure

Post Syndicated from Bruce Schneier original https://www.schneier.com/blog/archives/2018/06/e-mail_vulnerab.html

Last week, researchers disclosed vulnerabilities in a large number of encrypted e-mail clients: specifically, those that use OpenPGP and S/MIME, including Thunderbird and AppleMail. These are serious vulnerabilities: An attacker who can alter mail sent to a vulnerable client can trick that client into sending a copy of the plaintext to a web server controlled by that attacker. The story of these vulnerabilities and the tale of how they were disclosed illustrate some important lessons about security vulnerabilities in general and e-mail security in particular.

But first, if you use PGP or S/MIME to encrypt e-mail, you need to check the list on this page and see if you are vulnerable. If you are, check with the vendor to see if they’ve fixed the vulnerability. (Note that some early patches turned out not to fix the vulnerability.) If not, stop using the encrypted e-mail program entirely until it’s fixed. Or, if you know how to do it, turn off your e-mail client’s ability to process HTML e-mail or — even better — stop decrypting e-mails from within the client. There’s even more complex advice for more sophisticated users, but if you’re one of those, you don’t need me to explain this to you.

Consider your encrypted e-mail insecure until this is fixed.

All software contains security vulnerabilities, and one of the primary ways we all improve our security is by researchers discovering those vulnerabilities and vendors patching them. It’s a weird system: Corporate researchers are motivated by publicity, academic researchers by publication credentials, and just about everyone by individual fame and the small bug-bounties paid by some vendors.

Software vendors, on the other hand, are motivated to fix vulnerabilities by the threat of public disclosure. Without the threat of eventual publication, vendors are likely to ignore researchers and delay patching. This happened a lot in the 1990s, and even today, vendors often use legal tactics to try to block publication. It makes sense; they look bad when their products are pronounced insecure.

Over the past few years, researchers have started to choreograph vulnerability announcements to make a big press splash. Clever names — the e-mail vulnerability is called “Efail” — websites, and cute logos are now common. Key reporters are given advance information about the vulnerabilities. Sometimes advance teasers are released. Vendors are now part of this process, trying to announce their patches at the same time the vulnerabilities are announced.

This simultaneous announcement is best for security. While it’s always possible that some organization — either government or criminal — has independently discovered and is using the vulnerability before the researchers go public, use of the vulnerability is essentially guaranteed after the announcement. The time period between announcement and patching is the most dangerous, and everyone except would-be attackers wants to minimize it.

Things get much more complicated when multiple vendors are involved. In this case, Efail isn’t a vulnerability in a particular product; it’s a vulnerability in a standard that is used in dozens of different products. As such, the researchers had to ensure both that everyone knew about the vulnerability in time to fix it and that no one leaked the vulnerability to the public during that time. As you can imagine, that’s close to impossible.

Efail was discovered sometime last year, and the researchers alerted dozens of different companies between last October and March. Some companies took the news more seriously than others. Most patched. Amazingly, news about the vulnerability didn’t leak until the day before the scheduled announcement date. Two days before the scheduled release, the researchers unveiled a teaser — honestly, a really bad idea — which resulted in details leaking.

After the leak, the Electronic Frontier Foundation posted a notice about the vulnerability without details. The organization has been criticized for its announcement, but I am hard-pressed to find fault with its advice. (Note: I am a board member at EFF.) Then, the researchers published — and lots of press followed.

All of this speaks to the difficulty of coordinating vulnerability disclosure when it involves a large number of companies or — even more problematic — communities without clear ownership. And that’s what we have with OpenPGP. It’s even worse when the bug involves the interaction between different parts of a system. In this case, there’s nothing wrong with PGP or S/MIME in and of themselves. Rather, the vulnerability occurs because of the way many e-mail programs handle encrypted e-mail. GnuPG, an implementation of OpenPGP, decided that the bug wasn’t its fault and did nothing about it. This is arguably true, but irrelevant. They should fix it.

Expect more of these kinds of problems in the future. The Internet is shifting from a set of systems we deliberately use — our phones and computers — to a fully immersive Internet-of-things world that we live in 24/7. And like this e-mail vulnerability, vulnerabilities will emerge through the interactions of different systems. Sometimes it will be obvious who should fix the problem. Sometimes it won’t be. Sometimes it’ll be two secure systems that, when they interact in a particular way, cause an insecurity. In April, I wrote about a vulnerability that arose because Google and Netflix make different assumptions about e-mail addresses. I don’t even know who to blame for that one.

It gets even worse. Our system of disclosure and patching assumes that vendors have the expertise and ability to patch their systems, but that simply isn’t true for many of the embedded and low-cost Internet of things software packages. They’re designed at a much lower cost, often by offshore teams that come together, create the software, and then disband; as a result, there simply isn’t anyone left around to receive vulnerability alerts from researchers and write patches. Even worse, many of these devices aren’t patchable at all. Right now, if you own a digital video recorder that’s vulnerable to being recruited for a botnet — remember Mirai from 2016? — the only way to patch it is to throw it away and buy a new one.

Patching is starting to fail, which means that we’re losing the best mechanism we have for improving software security at exactly the same time that software is gaining autonomy and physical agency. Many researchers and organizations, including myself, have proposed government regulations enforcing minimal security standards for Internet-of-things devices, including standards around vulnerability disclosure and patching. This would be expensive, but it’s hard to see any other viable alternative.

Getting back to e-mail, the truth is that it’s incredibly difficult to secure well. Not because the cryptography is hard, but because we expect e-mail to do so many things. We use it for correspondence, for conversations, for scheduling, and for record-keeping. I regularly search my 20-year e-mail archive. The PGP and S/MIME security protocols are outdated, needlessly complicated and have been difficult to properly use the whole time. If we could start again, we would design something better and more user friendly­but the huge number of legacy applications that use the existing standards mean that we can’t. I tell people that if they want to communicate securely with someone, to use one of the secure messaging systems: Signal, Off-the-Record, or — if having one of those two on your system is itself suspicious — WhatsApp. Of course they’re not perfect, as last week’s announcement of a vulnerability (patched within hours) in Signal illustrates. And they’re not as flexible as e-mail, but that makes them easier to secure.

This essay previously appeared on Lawfare.com.

Storing Encrypted Credentials In Git

Post Syndicated from Bozho original https://techblog.bozho.net/storing-encrypted-credentials-in-git/

We all know that we should not commit any passwords or keys to the repo with our code (no matter if public or private). Yet, thousands of production passwords can be found on GitHub (and probably thousands more in internal company repositories). Some have tried to fix that by removing the passwords (once they learned it’s not a good idea to store them publicly), but passwords have remained in the git history.

Knowing what not to do is the first and very important step. But how do we store production credentials. Database credentials, system secrets (e.g. for HMACs), access keys for 3rd party services like payment providers or social networks. There doesn’t seem to be an agreed upon solution.

I’ve previously argued with the 12-factor app recommendation to use environment variables – if you have a few that might be okay, but when the number of variables grow (as in any real application), it becomes impractical. And you can set environment variables via a bash script, but you’d have to store it somewhere. And in fact, even separate environment variables should be stored somewhere.

This somewhere could be a local directory (risky), a shared storage, e.g. FTP or S3 bucket with limited access, or a separate git repository. I think I prefer the git repository as it allows versioning (Note: S3 also does, but is provider-specific). So you can store all your environment-specific properties files with all their credentials and environment-specific configurations in a git repo with limited access (only Ops people). And that’s not bad, as long as it’s not the same repo as the source code.

Such a repo would look like this:

project
└─── production
|   |   application.properites
|   |   keystore.jks
└─── staging
|   |   application.properites
|   |   keystore.jks
└─── on-premise-client1
|   |   application.properites
|   |   keystore.jks
└─── on-premise-client2
|   |   application.properites
|   |   keystore.jks

Since many companies are using GitHub or BitBucket for their repositories, storing production credentials on a public provider may still be risky. That’s why it’s a good idea to encrypt the files in the repository. A good way to do it is via git-crypt. It is “transparent” encryption because it supports diff and encryption and decryption on the fly. Once you set it up, you continue working with the repo as if it’s not encrypted. There’s even a fork that works on Windows.

You simply run git-crypt init (after you’ve put the git-crypt binary on your OS Path), which generates a key. Then you specify your .gitattributes, e.g. like that:

secretfile filter=git-crypt diff=git-crypt
*.key filter=git-crypt diff=git-crypt
*.properties filter=git-crypt diff=git-crypt
*.jks filter=git-crypt diff=git-crypt

And you’re done. Well, almost. If this is a fresh repo, everything is good. If it is an existing repo, you’d have to clean up your history which contains the unencrypted files. Following these steps will get you there, with one addition – before calling git commit, you should call git-crypt status -f so that the existing files are actually encrypted.

You’re almost done. We should somehow share and backup the keys. For the sharing part, it’s not a big issue to have a team of 2-3 Ops people share the same key, but you could also use the GPG option of git-crypt (as documented in the README). What’s left is to backup your secret key (that’s generated in the .git/git-crypt directory). You can store it (password-protected) in some other storage, be it a company shared folder, Dropbox/Google Drive, or even your email. Just make sure your computer is not the only place where it’s present and that it’s protected. I don’t think key rotation is necessary, but you can devise some rotation procedure.

git-crypt authors claim to shine when it comes to encrypting just a few files in an otherwise public repo. And recommend looking at git-remote-gcrypt. But as often there are non-sensitive parts of environment-specific configurations, you may not want to encrypt everything. And I think it’s perfectly fine to use git-crypt even in a separate repo scenario. And even though encryption is an okay approach to protect credentials in your source code repo, it’s still not necessarily a good idea to have the environment configurations in the same repo. Especially given that different people/teams manage these credentials. Even in small companies, maybe not all members have production access.

The outstanding questions in this case is – how do you sync the properties with code changes. Sometimes the code adds new properties that should be reflected in the environment configurations. There are two scenarios here – first, properties that could vary across environments, but can have default values (e.g. scheduled job periods), and second, properties that require explicit configuration (e.g. database credentials). The former can have the default values bundled in the code repo and therefore in the release artifact, allowing external files to override them. The latter should be announced to the people who do the deployment so that they can set the proper values.

The whole process of having versioned environment-speific configurations is actually quite simple and logical, even with the encryption added to the picture. And I think it’s a good security practice we should try to follow.

The post Storing Encrypted Credentials In Git appeared first on Bozho's tech blog.

The First Lady’s bad cyber advice

Post Syndicated from Robert Graham original https://blog.erratasec.com/2018/05/the-first-ladys-bad-cyber-advice.html

First Lady Melania Trump announced a guide to help children go online safely. It has problems.

Melania’s guide is full of outdated, impractical, inappropriate, and redundant information. But that’s allowed, because it relies upon moral authority: to be moral is to be secure, to be moral is to do what the government tells you. It matters less whether the advice is technically accurate, and more that you are supposed to do what authority tells you.

That’s a problem, not just with her guide, but most cybersecurity advice in general. Our community gives out advice without putting much thought into it, because it doesn’t need thought. You should do what we tell you, because being secure is your moral duty.

This post picks apart Melania’s document. The purpose isn’t to fine-tune her guide and make it better. Instead, the purpose is to demonstrate the idea of resting on moral authority instead of technical authority.
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Strong Passwords

“Strong passwords” is the quintessential cybersecurity cliché that insecurity is due to some “weakness” (laziness, ignorance, greed, etc.) and the remedy is to be “strong”.

The first flaw is that this advice is outdated. Ten years ago, important websites would frequently get hacked and have poor password protection (like MD5 hashing). Back then, strength mattered, to stop hackers from brute force guessing the hacked passwords. These days, important websites get hacked less often and protect the passwords better (like salted bcrypt). Moreover, the advice is now often redundant: websites, at least the important ones, enforce a certain level of password complexity, so that even without advice, you’ll be forced to do the right thing most of the time.

This advice is outdated for a second reason: hackers have gotten a lot better at cracking passwords. Ten years ago, they focused on brute force, trying all possible combinations. Partly because passwords are now protected better, dramatically reducing the effectiveness of the brute force approach, hackers have had to focus on other techniques, such as the mutated dictionary and Markov chain attacks. Consequently, even though “Password123!” seems to meet the above criteria of a strong password, it’ll fall quickly to a mutated dictionary attack. The simple recommendation of “strong passwords” is no longer sufficient.

The last part of the above advice is to avoid password reuse. This is good advice. However, this becomes impractical advice, especially when the user is trying to create “strong” complex passwords as described above. There’s no way users/children can remember that many passwords. So they aren’t going to follow that advice.

To make the advice work, you need to help users with this problem. To begin with, you need to tell them to write down all their passwords. This is something many people avoid, because they’ve been told to be “strong” and writing down passwords seems “weak”. Indeed it is, if you write them down in an office environment and stick them on a note on the monitor or underneath the keyboard. But they are safe and strong if it’s on paper stored in your home safe, or even in a home office drawer. I write my passwords on the margins in a book on my bookshelf — even if you know that, it’ll take you a long time to figure out which book when invading my home.

The other option to help avoid password reuse is to use a password manager. I don’t recommend them to my own parents because that’d be just one more thing I’d have to help them with, but they are fairly easy to use. It means you need only one password for the password manager, which then manages random/complex passwords for all your web accounts.

So what we have here is outdated and redundant advice that overshadows good advice that is nonetheless incomplete and impractical. The advice is based on the moral authority of telling users to be “strong” rather than the practical advice that would help them.

No personal info unless website is secure

The guide teaches kids to recognize the difference between a secure/trustworthy and insecure website. This is laughably wrong.

HTTPS means the connection to the website is secure, not that the website is secure. These are different things. It means hackers are unlikely to be able to eavesdrop on the traffic as it’s transmitted to the website. However, the website itself may be insecure (easily hacked), or worse, it may be a fraudulent website created by hackers to appear similar to a legitimate website.

What HTTPS secures is a common misconception, perpetuated by guides like this. This is the source of criticism for LetsEncrypt, an initiative to give away free website certificates so that everyone can get HTTPS. Hackers now routinely use LetsEncrypt to create their fraudulent websites to host their viruses. Since people have been taught forever that HTTPS means a website is “secure”, people are trusting these hacker websites.

But LetsEncrypt is a good thing, all connections should be secure. What’s bad is not LetsEncrypt itself, but guides like this from the government that have for years been teaching people the wrong thing, that HTTPS means a website is secure.

Backups

Of course, no guide would be complete without telling people to backup their stuff.

This is especially important with the growing ransomware threat. Ransomware is a type of virus/malware that encrypts your files then charges you money to get the key to decrypt the files. Half the time this just destroys the files.

But this again is moral authority, telling people what to do, instead of educating them how to do it. Most will ignore this advice because they don’t know how to effectively backup their stuff.

For most users, it’s easy to go to the store and buy a 256-gigabyte USB drive for $40 (as of May 2018) then use the “Timemachine” feature in macOS, or on Windows the “File History” feature or the “Backup and Restore” feature. These can be configured to automatically do the backup on a regular basis so that you don’t have to worry about it.

But such “local” backups are still problematic. If the drive is left plugged into the machine, ransomeware can attack the backup. If there’s a fire, any backup in your home will be destroyed along with the computer.

I recommend cloud backup instead. There are so many good providers, like DropBox, Backblaze, Microsoft, Apple’s iCloud, and so on. These are especially critical for phones: if your iPhone is destroyed or stolen, you can simply walk into an Apple store and buy a new one, with everything replaced as it was from their iCloud.

But all of this is missing the key problem: your photos. You carry a camera with you all the time now and take a lot of high resolution photos. This quickly exceeds the capacity of most of the free backup solutions. You can configure these, such as you phone’s iCloud backup, to exclude photos, but that means you are prone to losing your photos/memories. For example, Drop Box is great for the free 5 gigabyte service, but if I want to preserve photos on it, I have to pay for their more expensive service.

One of the key messages kids should learn about photos is that they will likely lose most all of the photos they’ve taken within 5 years. The exceptions will be the few photos they’ve posted to social media, which sorta serves as a cloud backup for them. If they want to preserve the rest of these memories, the kids need to take seriously finding backup solutions. I’m not sure of the best solution, but I buy big USB flash drives and send them to my niece asking her to copy all her photos to them, so that at least I can put that in a safe.

One surprisingly good solution is Microsoft Office 365. For $99 a year, you get a copy of their Office software (which I use) but it also comes with a large 1-terabyte of cloud storage, which is likely big enough for your photos. Apple charges around the same amount for 1-terabyte of iCloud, though it doesn’t come with a free license for Microsoft Office :-).

WiFi encryption

Your home WiFi should be encrypted, of course.

I have to point out the language, though. Turning on WPA2 WiFi encryption does not “secure your network”. Instead, it just secures the radio signals from being eavesdropped. Your network may have other vulnerabilities, where encryption won’t help, such as when your router has remote administration turned on with a default or backdoor password enabled.

I’m being a bit pedantic here, but it’s not my argument. It’s the FTC’s argument when they sued vendors like D-Link for making exactly the same sort of recommendation. The FTC claimed it was deceptive business practice because recommending users do things like this still didn’t mean the device was “secure”. Since the FTC is partly responsible for writing Melania’s document, I find this a bit ironic.

In any event, WPA2 personal has problems where it can be hacked, such as if WPS is enabled, or evil twin access-points broadcasting stronger (or more directional) signals. It’s thus insufficient security. To be fully secure against possible WiFi eavesdropping you need to enable enterprise WPA2, which isn’t something most users can do.

Also, WPA2 is largely redundant. If you wardrive your local neighborhood you’ll find that almost everyone has WPA enabled already anyway. Guides like this probably don’t need to advise what everyone’s already doing, especially when it’s still incomplete.

Change your router password

Yes, leaving the default password on your router is a problem, as shown by recent Mirai-style attacks, such as the very recent ones where Russia has infected 500,000 in their cyberwar against Ukraine. But those were only a problem because routers also had remote administration enabled. It’s remote administration you need to make sure is disabled on your router, regardless if you change the default password (as there are other vulnerabilities besides passwords). If remote administration is disabled, then it’s very rare that people will attack your router with the default password.

Thus, they ignore the important thing (remote administration) and instead focus on the less important thing (change default password).

In addition, this advice again the impractical recommendation of choosing a complex (strong) password. Users who do this usually forget it by the time they next need it. Practical advice is to recommend users write down the password they choose, and put it either someplace they won’t forget (like with the rest of their passwords), or on a sticky note under the router.

Update router firmware

Like any device on the network, you should keep it up-to-date with the latest patches. But you aren’t going to, because it’s not practical. While your laptop/desktop and phone nag you about updates, your router won’t. Whereas phones/computers update once a month, your router vendor will update the firmware once a year — and after a few years, stop releasing any more updates at all.

Routers are just one of many IoT devices we are going to have to come to terms with, keeping them patched. I don’t know the right answer. I check my parents stuff every Thanksgiving, so maybe that’s a good strategy: patch your stuff at the end of every year. Maybe some cultural norms will develop, but simply telling people to be strong about their IoT firmware patches isn’t going to be practical in the near term.

Don’t click on stuff

This probably the most common cybersecurity advice given by infosec professionals. It is wrong.

Emails/messages are designed for you to click on things. You regularly get emails/messages from legitimate sources that demand you click on things. It’s so common from legitimate sources that there’s no practical way for users to distinguish between them and bad sources. As that Google Docs bug showed, even experts can’t always tell the difference.

I mean, it’s true that phishing attacks coming through emails/messages try to trick you into clicking on things, and you should be suspicious of such things. However, it doesn’t follow from this that not clicking on things is a practical strategy. It’s like diet advice recommending you stop eating food altogether.

Sex predators, oh my!

Of course, its kids going online, so of course you are going to have warnings about sexual predators:

But online predators are rare. The predator threat to children is overwhelmingly from relatives and acquaintances, a much smaller threat from strangers, and a vanishingly tiny threat from online predators. Recommendations like this stem from our fears of the unknown technology rather than a rational measurement of the threat.

Sexting, oh my!

So here is one piece of advice that I can agree with: don’t sext:

But the reason this is bad is not because it’s immoral or wrong, but because adults have gone crazy and made it illegal for children to take nude photographs of themselves. As this article points out, your child is more likely to get in trouble and get placed on the sex offender registry (for life) than to get molested by a person on that registry.

Thus, we need to warn kids not from some immoral activity, but from adults who’ve gotten freaked out about it. Yes, sending pictures to your friends/love-interest will also often get you in trouble as those images will frequently get passed around school, but such temporary embarrassments will pass. Getting put on a sex offender registry harms you for life.

Texting while driving

Finally, I want to point out this error:

The evidence is to the contrary, that it’s not actually dangerous — it’s just assumed to be dangerous. Texting rarely distracts drivers from what’s going on the road. It instead replaces some other inattention, such as day dreaming, fiddling with the radio, or checking yourself in the mirror. Risk compensation happens, when people are texting while driving, they are also slowing down and letting more space between them and the car in front of them.

Studies have shown this. For example, one study measured accident rates at 6:59pm vs 7:01pm and found no difference. That’s when “free evening texting” came into effect, so we should’ve seen a bump in the number of accidents. They even tried to narrow the effect down, such as people texting while changing cell towers (proving they were in motion).

Yes, texting is illegal, but that’s because people are fed up with the jerk in front of them not noticing the light is green. It’s not illegal because it’s particularly dangerous, that it has a measurable impact on accident rates.

Conclusion

The point of this post is not to refine the advice and make it better. Instead, I attempt to demonstrate how such advice rests on moral authority, because it’s the government telling you so. It’s because cybersecurity and safety are higher moral duties. Much of it is outdated, impractical, inappropriate, and redundant.
We need to move away from this sort of advice. Instead of moral authority, we need technical authority. We need to focus on the threats that people actually face, and instead of commanding them what to do. We need to help them be secure, not command to command them, shaming them for their insecurity. It’s like Strunk and White’s “Elements of Style”: they don’t take the moral authority approach and tell people how to write, but instead try to help people how to write well.

Amazon Neptune Generally Available

Post Syndicated from Randall Hunt original https://aws.amazon.com/blogs/aws/amazon-neptune-generally-available/

Amazon Neptune is now Generally Available in US East (N. Virginia), US East (Ohio), US West (Oregon), and EU (Ireland). Amazon Neptune is a fast, reliable, fully-managed graph database service that makes it easy to build and run applications that work with highly connected datasets. At the core of Neptune is a purpose-built, high-performance graph database engine optimized for storing billions of relationships and querying the graph with millisecond latencies. Neptune supports two popular graph models, Property Graph and RDF, through Apache TinkerPop Gremlin and SPARQL, allowing you to easily build queries that efficiently navigate highly connected datasets. Neptune can be used to power everything from recommendation engines and knowledge graphs to drug discovery and network security. Neptune is fully-managed with automatic minor version upgrades, backups, encryption, and fail-over. I wrote about Neptune in detail for AWS re:Invent last year and customers have been using the preview and providing great feedback that the team has used to prepare the service for GA.

Now that Amazon Neptune is generally available there are a few changes from the preview:

Launching an Amazon Neptune Cluster

Launching a Neptune cluster is as easy as navigating to the AWS Management Console and clicking create cluster. Of course you can also launch with CloudFormation, the CLI, or the SDKs.

You can monitor your cluster health and the health of individual instances through Amazon CloudWatch and the console.

Additional Resources

We’ve created two repos with some additional tools and examples here. You can expect continuous development on these repos as we add additional tools and examples.

  • Amazon Neptune Tools Repo
    This repo has a useful tool for converting GraphML files into Neptune compatible CSVs for bulk loading from S3.
  • Amazon Neptune Samples Repo
    This repo has a really cool example of building a collaborative filtering recommendation engine for video game preferences.

Purpose Built Databases

There’s an industry trend where we’re moving more and more onto purpose-built databases. Developers and businesses want to access their data in the format that makes the most sense for their applications. As cloud resources make transforming large datasets easier with tools like AWS Glue, we have a lot more options than we used to for accessing our data. With tools like Amazon Redshift, Amazon Athena, Amazon Aurora, Amazon DynamoDB, and more we get to choose the best database for the job or even enable entirely new use-cases. Amazon Neptune is perfect for workloads where the data is highly connected across data rich edges.

I’m really excited about graph databases and I see a huge number of applications. Looking for ideas of cool things to build? I’d love to build a web crawler in AWS Lambda that uses Neptune as the backing store. You could further enrich it by running Amazon Comprehend or Amazon Rekognition on the text and images found and creating a search engine on top of Neptune.

As always, feel free to reach out in the comments or on twitter to provide any feedback!

Randall

Getting Rid of Your Mac? Here’s How to Securely Erase a Hard Drive or SSD

Post Syndicated from Roderick Bauer original https://www.backblaze.com/blog/how-to-wipe-a-mac-hard-drive/

erasing a hard drive and a solid state drive

What do I do with a Mac that still has personal data on it? Do I take out the disk drive and smash it? Do I sweep it with a really strong magnet? Is there a difference in how I handle a hard drive (HDD) versus a solid-state drive (SSD)? Well, taking a sledgehammer or projectile weapon to your old machine is certainly one way to make the data irretrievable, and it can be enormously cathartic as long as you follow appropriate safety and disposal protocols. But there are far less destructive ways to make sure your data is gone for good. Let me introduce you to secure erasing.

Which Type of Drive Do You Have?

Before we start, you need to know whether you have a HDD or a SSD. To find out, or at least to make sure, you click on the Apple menu and select “About this Mac.” Once there, select the “Storage” tab to see which type of drive is in your system.

The first example, below, shows a SATA Disk (HDD) in the system.

SATA HDD

In the next case, we see we have a Solid State SATA Drive (SSD), plus a Mac SuperDrive.

Mac storage dialog showing SSD

The third screen shot shows an SSD, as well. In this case it’s called “Flash Storage.”

Flash Storage

Make Sure You Have a Backup

Before you get started, you’ll want to make sure that any important data on your hard drive has moved somewhere else. OS X’s built-in Time Machine backup software is a good start, especially when paired with Backblaze. You can learn more about using Time Machine in our Mac Backup Guide.

With a local backup copy in hand and secure cloud storage, you know your data is always safe no matter what happens.

Once you’ve verified your data is backed up, roll up your sleeves and get to work. The key is OS X Recovery — a special part of the Mac operating system since OS X 10.7 “Lion.”

How to Wipe a Mac Hard Disk Drive (HDD)

NOTE: If you’re interested in wiping an SSD, see below.

    1. Make sure your Mac is turned off.
    2. Press the power button.
    3. Immediately hold down the command and R keys.
    4. Wait until the Apple logo appears.
    5. Select “Disk Utility” from the OS X Utilities list. Click Continue.
    6. Select the disk you’d like to erase by clicking on it in the sidebar.
    7. Click the Erase button.
    8. Click the Security Options button.
    9. The Security Options window includes a slider that enables you to determine how thoroughly you want to erase your hard drive.

There are four notches to that Security Options slider. “Fastest” is quick but insecure — data could potentially be rebuilt using a file recovery app. Moving that slider to the right introduces progressively more secure erasing. Disk Utility’s most secure level erases the information used to access the files on your disk, then writes zeroes across the disk surface seven times to help remove any trace of what was there. This setting conforms to the DoD 5220.22-M specification.

  1. Once you’ve selected the level of secure erasing you’re comfortable with, click the OK button.
  2. Click the Erase button to begin. Bear in mind that the more secure method you select, the longer it will take. The most secure methods can add hours to the process.

Once it’s done, the Mac’s hard drive will be clean as a whistle and ready for its next adventure: a fresh installation of OS X, being donated to a relative or a local charity, or just sent to an e-waste facility. Of course you can still drill a hole in your disk or smash it with a sledgehammer if it makes you happy, but now you know how to wipe the data from your old computer with much less ruckus.

The above instructions apply to older Macintoshes with HDDs. What do you do if you have an SSD?

Securely Erasing SSDs, and Why Not To

Most new Macs ship with solid state drives (SSDs). Only the iMac and Mac mini ship with regular hard drives anymore, and even those are available in pure SSD variants if you want.

If your Mac comes equipped with an SSD, Apple’s Disk Utility software won’t actually let you zero the hard drive.

Wait, what?

In a tech note posted to Apple’s own online knowledgebase, Apple explains that you don’t need to securely erase your Mac’s SSD:

With an SSD drive, Secure Erase and Erasing Free Space are not available in Disk Utility. These options are not needed for an SSD drive because a standard erase makes it difficult to recover data from an SSD.

In fact, some folks will tell you not to zero out the data on an SSD, since it can cause wear and tear on the memory cells that, over time, can affect its reliability. I don’t think that’s nearly as big an issue as it used to be — SSD reliability and longevity has improved.

If “Standard Erase” doesn’t quite make you feel comfortable that your data can’t be recovered, there are a couple of options.

FileVault Keeps Your Data Safe

One way to make sure that your SSD’s data remains secure is to use FileVault. FileVault is whole-disk encryption for the Mac. With FileVault engaged, you need a password to access the information on your hard drive. Without it, that data is encrypted.

There’s one potential downside of FileVault — if you lose your password or the encryption key, you’re screwed: You’re not getting your data back any time soon. Based on my experience working at a Mac repair shop, losing a FileVault key happens more frequently than it should.

When you first set up a new Mac, you’re given the option of turning FileVault on. If you don’t do it then, you can turn on FileVault at any time by clicking on your Mac’s System Preferences, clicking on Security & Privacy, and clicking on the FileVault tab. Be warned, however, that the initial encryption process can take hours, as will decryption if you ever need to turn FileVault off.

With FileVault turned on, you can restart your Mac into its Recovery System (by restarting the Mac while holding down the command and R keys) and erase the hard drive using Disk Utility, once you’ve unlocked it (by selecting the disk, clicking the File menu, and clicking Unlock). That deletes the FileVault key, which means any data on the drive is useless.

FileVault doesn’t impact the performance of most modern Macs, though I’d suggest only using it if your Mac has an SSD, not a conventional hard disk drive.

Securely Erasing Free Space on Your SSD

If you don’t want to take Apple’s word for it, if you’re not using FileVault, or if you just want to, there is a way to securely erase free space on your SSD. It’s a little more involved but it works.

Before we get into the nitty-gritty, let me state for the record that this really isn’t necessary to do, which is why Apple’s made it so hard to do. But if you’re set on it, you’ll need to use Apple’s Terminal app. Terminal provides you with command line interface access to the OS X operating system. Terminal lives in the Utilities folder, but you can access Terminal from the Mac’s Recovery System, as well. Once your Mac has booted into the Recovery partition, click the Utilities menu and select Terminal to launch it.

From a Terminal command line, type:

diskutil secureErase freespace VALUE /Volumes/DRIVE

That tells your Mac to securely erase the free space on your SSD. You’ll need to change VALUE to a number between 0 and 4. 0 is a single-pass run of zeroes; 1 is a single-pass run of random numbers; 2 is a 7-pass erase; 3 is a 35-pass erase; and 4 is a 3-pass erase. DRIVE should be changed to the name of your hard drive. To run a 7-pass erase of your SSD drive in “JohnB-Macbook”, you would enter the following:

diskutil secureErase freespace 2 /Volumes/JohnB-Macbook

And remember, if you used a space in the name of your Mac’s hard drive, you need to insert a leading backslash before the space. For example, to run a 35-pass erase on a hard drive called “Macintosh HD” you enter the following:

diskutil secureErase freespace 3 /Volumes/Macintosh\ HD

Something to remember is that the more extensive the erase procedure, the longer it will take.

When Erasing is Not Enough — How to Destroy a Drive

If you absolutely, positively need to be sure that all the data on a drive is irretrievable, see this Scientific American article (with contributions by Gleb Budman, Backblaze CEO), How to Destroy a Hard Drive — Permanently.

The post Getting Rid of Your Mac? Here’s How to Securely Erase a Hard Drive or SSD appeared first on Backblaze Blog | Cloud Storage & Cloud Backup.

EC2 Instance Update – C5 Instances with Local NVMe Storage (C5d)

Post Syndicated from Jeff Barr original https://aws.amazon.com/blogs/aws/ec2-instance-update-c5-instances-with-local-nvme-storage-c5d/

As you can see from my EC2 Instance History post, we add new instance types on a regular and frequent basis. Driven by increasingly powerful processors and designed to address an ever-widening set of use cases, the size and diversity of this list reflects the equally diverse group of EC2 customers!

Near the bottom of that list you will find the new compute-intensive C5 instances. With a 25% to 50% improvement in price-performance over the C4 instances, the C5 instances are designed for applications like batch and log processing, distributed and or real-time analytics, high-performance computing (HPC), ad serving, highly scalable multiplayer gaming, and video encoding. Some of these applications can benefit from access to high-speed, ultra-low latency local storage. For example, video encoding, image manipulation, and other forms of media processing often necessitates large amounts of I/O to temporary storage. While the input and output files are valuable assets and are typically stored as Amazon Simple Storage Service (S3) objects, the intermediate files are expendable. Similarly, batch and log processing runs in a race-to-idle model, flushing volatile data to disk as fast as possible in order to make full use of compute resources.

New C5d Instances with Local Storage
In order to meet this need, we are introducing C5 instances equipped with local NVMe storage. Available for immediate use in 5 regions, these instances are a great fit for the applications that I described above, as well as others that you will undoubtedly dream up! Here are the specs:

Instance Name vCPUs RAM Local Storage EBS Bandwidth Network Bandwidth
c5d.large 2 4 GiB 1 x 50 GB NVMe SSD Up to 2.25 Gbps Up to 10 Gbps
c5d.xlarge 4 8 GiB 1 x 100 GB NVMe SSD Up to 2.25 Gbps Up to 10 Gbps
c5d.2xlarge 8 16 GiB 1 x 225 GB NVMe SSD Up to 2.25 Gbps Up to 10 Gbps
c5d.4xlarge 16 32 GiB 1 x 450 GB NVMe SSD 2.25 Gbps Up to 10 Gbps
c5d.9xlarge 36 72 GiB 1 x 900 GB NVMe SSD 4.5 Gbps 10 Gbps
c5d.18xlarge 72 144 GiB 2 x 900 GB NVMe SSD 9 Gbps 25 Gbps

Other than the addition of local storage, the C5 and C5d share the same specs. Both are powered by 3.0 GHz Intel Xeon Platinum 8000-series processors, optimized for EC2 and with full control over C-states on the two largest sizes, giving you the ability to run two cores at up to 3.5 GHz using Intel Turbo Boost Technology.

You can use any AMI that includes drivers for the Elastic Network Adapter (ENA) and NVMe; this includes the latest Amazon Linux, Microsoft Windows (Server 2008 R2, Server 2012, Server 2012 R2 and Server 2016), Ubuntu, RHEL, SUSE, and CentOS AMIs.

Here are a couple of things to keep in mind about the local NVMe storage:

Naming – You don’t have to specify a block device mapping in your AMI or during the instance launch; the local storage will show up as one or more devices (/dev/nvme*1 on Linux) after the guest operating system has booted.

Encryption – Each local NVMe device is hardware encrypted using the XTS-AES-256 block cipher and a unique key. Each key is destroyed when the instance is stopped or terminated.

Lifetime – Local NVMe devices have the same lifetime as the instance they are attached to, and do not stick around after the instance has been stopped or terminated.

Available Now
C5d instances are available in On-Demand, Reserved Instance, and Spot form in the US East (N. Virginia), US West (Oregon), EU (Ireland), US East (Ohio), and Canada (Central) Regions. Prices vary by Region, and are just a bit higher than for the equivalent C5 instances.

Jeff;

PS – We will be adding local NVMe storage to other EC2 instance types in the months to come, so stay tuned!

Connect Veeam to the B2 Cloud: Episode 3 — Using OpenDedup

Post Syndicated from Roderick Bauer original https://www.backblaze.com/blog/opendedup-for-cloud-storage/

Veeam backup to Backblaze B2 logo

In this, the third post in our series on connecting Veeam with Backblaze B2 Cloud Storage, we discuss how to back up your VMs to B2 using Veeam and OpenDedup. In our previous posts, we covered how to connect Veeam to the B2 cloud using Synology, and how to connect Veeam with B2 using StarWind VTL.

Deduplication and OpenDedup

Deduplication is simply the process of eliminating redundant data on disk. Deduplication reduces storage space requirements, improves backup speed, and lowers backup storage costs. The dedup field used to be dominated by a few big-name vendors who sold dedup systems that were too expensive for most of the SMB market. Then an open-source challenger came along in OpenDedup, a project that produced the Space Deduplication File System (SDFS). SDFS provides many of the features of commercial dedup products without their cost.

OpenDedup provides inline deduplication that can be used with applications such as Veeam, Veritas Backup Exec, and Veritas NetBackup.

Features Supported by OpenDedup:

  • Variable Block Deduplication to cloud storage
  • Local Data Caching
  • Encryption
  • Bandwidth Throttling
  • Fast Cloud Recovery
  • Windows and Linux Support

Why use Veeam with OpenDedup to Backblaze B2?

With your VMs backed up to B2, you have a number of options to recover from a disaster. If the unexpected occurs, you can quickly restore your VMs from B2 to the location of your choosing. You also have the option to bring up cloud compute through B2’s compute partners, thereby minimizing any loss of service and ensuring business continuity.

Veeam logo  +  OpenDedup logo  +  Backblaze B2 logo

Backblaze’s B2 is an ideal solution for backing up Veeam’s backup repository due to B2’s combination of low-cost and high availability. Users of B2 save up to 75% compared to other cloud solutions such as Microsoft Azure, Amazon AWS, or Google Cloud Storage. When combined with OpenDedup’s no-cost deduplication, you’re got an efficient and economical solution for backing up VMs to the cloud.

How to Use OpenDedup with B2

For step-by-step instructions for how to set up OpenDedup for use with B2 on Windows or Linux, see Backblaze B2 Enabled on the OpenDedup website.

Are you backing up Veeam to B2 using one of the solutions we’ve written about in this series? If you have, we’d love to hear from you in the comments.

View all posts in the Veeam series.

The post Connect Veeam to the B2 Cloud: Episode 3 — Using OpenDedup appeared first on Backblaze Blog | Cloud Storage & Cloud Backup.

Details on a New PGP Vulnerability

Post Syndicated from Bruce Schneier original https://www.schneier.com/blog/archives/2018/05/details_on_a_ne.html

A new PGP vulnerability was announced today. Basically, the vulnerability makes use of the fact that modern e-mail programs allow for embedded HTML objects. Essentially, if an attacker can intercept and modify a message in transit, he can insert code that sends the plaintext in a URL to a remote website. Very clever.

The EFAIL attacks exploit vulnerabilities in the OpenPGP and S/MIME standards to reveal the plaintext of encrypted emails. In a nutshell, EFAIL abuses active content of HTML emails, for example externally loaded images or styles, to exfiltrate plaintext through requested URLs. To create these exfiltration channels, the attacker first needs access to the encrypted emails, for example, by eavesdropping on network traffic, compromising email accounts, email servers, backup systems or client computers. The emails could even have been collected years ago.

The attacker changes an encrypted email in a particular way and sends this changed encrypted email to the victim. The victim’s email client decrypts the email and loads any external content, thus exfiltrating the plaintext to the attacker.

A few initial comments:

1. Being able to intercept and modify e-mails in transit is the sort of thing the NSA can do, but is hard for the average hacker. That being said, there are circumstances where someone can modify e-mails. I don’t mean to minimize the seriousness of this attack, but that is a consideration.

2. The vulnerability isn’t with PGP or S/MIME itself, but in the way they interact with modern e-mail programs. You can see this in the two suggested short-term mitigations: “No decryption in the e-mail client,” and “disable HTML rendering.”

3. I’ve been getting some weird press calls from reporters wanting to know if this demonstrates that e-mail encryption is impossible. No, this just demonstrates that programmers are human and vulnerabilities are inevitable. PGP almost certainly has fewer bugs than your average piece of software, but it’s not bug free.

3. Why is anyone using encrypted e-mail anymore, anyway? Reliably and easily encrypting e-mail is an insurmountably hard problem for reasons having nothing to do with today’s announcement. If you need to communicate securely, use Signal. If having Signal on your phone will arouse suspicion, use WhatsApp.

I’ll post other commentaries and analyses as I find them.

EDITED TO ADD (5/14): News articles.

Slashdot thread.

Critical PGP Vulnerability

Post Syndicated from Bruce Schneier original https://www.schneier.com/blog/archives/2018/05/critical_pgp_vu.html

EFF is reporting that a critical vulnerability has been discovered in PGP and S/MIME. No details have been published yet, but one of the researchers wrote:

We’ll publish critical vulnerabilities in PGP/GPG and S/MIME email encryption on 2018-05-15 07:00 UTC. They might reveal the plaintext of encrypted emails, including encrypted emails sent in the past. There are currently no reliable fixes for the vulnerability. If you use PGP/GPG or S/MIME for very sensitive communication, you should disable it in your email client for now.

This sounds like a protocol vulnerability, but we’ll learn more tomorrow.

News articles.

Serious vulnerabilities with OpenPGP and S/MIME

Post Syndicated from corbet original https://lwn.net/Articles/754370/rss

The efail.de site describes a set of
vulnerabilities in the implementation of PGP and MIME that can cause the
disclosure of encrypted communications, including old messages. “In a
nutshell, EFAIL abuses active content of HTML emails, for example
externally loaded images or styles, to exfiltrate plaintext through
requested URLs.

The EFF recommends
uninstalling email-encryption tools that automatically
decrypt email entirely. “Until the flaws
described in the paper are more widely understood and fixed, users should
arrange for the use of alternative end-to-end secure channels, such as
Signal, and temporarily stop sending and especially reading PGP-encrypted
email.

‘Anonymous’ Hackers Deface Russian Govt. Site to Protest Web-Blocking (NSFW)

Post Syndicated from Andy original https://torrentfreak.com/anonymous-hackers-deface-russian-govt-site-to-protest-web-blocking-nsfw-180512/

Last month, Russian authorities demonstrated that when an entity breaks local Internet rules, no stone will be left unturned to make them pay, whatever the cost.

The disaster waiting to happen began when encrypted messaging service Telegram refused to hand over its encryption keys to the state. In response, the Federal Security Service filed a lawsuit, which it won, compelling it Telegram do so. With no response, Roscomnadzor obtained a court order to have Telegram blocked.

In a massive response, Russian ISPs – at Roscomnadzor’s behest – began mass-blocking IP addresses on a massive scale. Millions of IP addresses belong to Amazon, Google and other innocent parties were rendered inaccessible in Russia, causing chaos online.

Even VPN providers were targeted for facilitating access to Telegram but while the service strained under the pressure, it never went down and continues to function today.

In the wake of the operation there has been some attempt at a cleanup job, with Roscomnadzor announcing this week that it had unblocked millions of IP addresses belonging to Google.

“As part of a package of the measures to enforce the court’s decision on Telegram, Roskomnadzor has removed six Google subnets (more than 3.7 million IP-addresses) from the blocklist,” the telecoms watchdog said in a statement.

“In this case, the IP addresses of Telegram, which are part of these subnets, are fully installed and blocked. Subnets are unblocked in order to ensure the correct operation of third-party Internet resources.”

But while Roscomnadzor attempts to calm the seas, those angered by Russia’s carpet-bombing of the Internet were determined to make their voices heard. Hackers attacked the website of the Federal Agency for International Cooperation this week, defacing it with scathing criticism combined with NSFW suggestions and imagery.

“Greetings, Roskomnadzor,” the message began.

“Your recent destructive actions towards the Russian internet sector have led us to believe that you are nothing but a bunch of incompetent mindless worms. You shall not be able to continue this pointless vandalism any further.”

Signing off with advice to consider the defacement as a “final warning”, the hackers disappeared into the night after leaving a simple signature.

“Yours, Anonymous,” they wrote.

But the hackers weren’t done yet. In a NSFW cartoon strip that probably explains itself, ‘Anonymous’ suggested that Roscomnadzor should perhaps consider blocking itself, with the implement depicted in the final frame.

“Anus, block yourself Roscomnadzor”

But while Russia’s attack on Telegram raises eyebrows worldwide, the actions of those in authority continue to baffle.

Last week, Prime Minister Dmitry Medvedev’s press secretary, Natalia Timakova, publicly advised a colleague to circumvent the Telegram blockade using a VPN, effectively undermining the massive efforts of the authorities. This week the head of Roscomnadzor only added to the confusion.

Effectively quashing rumors that he’d resigned due to the Telegram fiasco, Alexander Zharov had a conversation with the editor-in-chief of radio station ‘Says Moscow’.

During the liason, which took place during the Victory Parade in Red Square, Zharov was asked how he could be contacted. When Telegram was presented as a potential method, Zharov confirmed that he could be reached via the platform.

Finally, in a move that’s hoped could bring an end to the attack on the platform and others like it, Telegram filed an appeal this week challenging a decision by the Supreme Court of Russia which allows the Federal Security Service to demand access to encryption keys.

Source: TF, for the latest info on copyright, file-sharing, torrent sites and more. We also have VPN reviews, discounts, offers and coupons.

Securing Your Cryptocurrency

Post Syndicated from Roderick Bauer original https://www.backblaze.com/blog/backing-up-your-cryptocurrency/

Securing Your Cryptocurrency

In our blog post on Tuesday, Cryptocurrency Security Challenges, we wrote about the two primary challenges faced by anyone interested in safely and profitably participating in the cryptocurrency economy: 1) make sure you’re dealing with reputable and ethical companies and services, and, 2) keep your cryptocurrency holdings safe and secure.

In this post, we’re going to focus on how to make sure you don’t lose any of your cryptocurrency holdings through accident, theft, or carelessness. You do that by backing up the keys needed to sell or trade your currencies.

$34 Billion in Lost Value

Of the 16.4 million bitcoins said to be in circulation in the middle of 2017, close to 3.8 million may have been lost because their owners no longer are able to claim their holdings. Based on today’s valuation, that could total as much as $34 billion dollars in lost value. And that’s just bitcoins. There are now over 1,500 different cryptocurrencies, and we don’t know how many of those have been misplaced or lost.



Now that some cryptocurrencies have reached (at least for now) staggering heights in value, it’s likely that owners will be more careful in keeping track of the keys needed to use their cryptocurrencies. For the ones already lost, however, the owners have been separated from their currencies just as surely as if they had thrown Benjamin Franklins and Grover Clevelands over the railing of a ship.

The Basics of Securing Your Cryptocurrencies

In our previous post, we reviewed how cryptocurrency keys work, and the common ways owners can keep track of them. A cryptocurrency owner needs two keys to use their currencies: a public key that can be shared with others is used to receive currency, and a private key that must be kept secure is used to spend or trade currency.

Many wallets and applications allow the user to require extra security to access them, such as a password, or iris, face, or thumb print scan. If one of these options is available in your wallets, take advantage of it. Beyond that, it’s essential to back up your wallet, either using the backup feature built into some applications and wallets, or manually backing up the data used by the wallet. When backing up, it’s a good idea to back up the entire wallet, as some wallets require additional private data to operate that might not be apparent.

No matter which backup method you use, it is important to back up often and have multiple backups, preferable in different locations. As with any valuable data, a 3-2-1 backup strategy is good to follow, which ensures that you’ll have a good backup copy if anything goes wrong with one or more copies of your data.

One more caveat, don’t reuse passwords. This applies to all of your accounts, but is especially important for something as critical as your finances. Don’t ever use the same password for more than one account. If security is breached on one of your accounts, someone could connect your name or ID with other accounts, and will attempt to use the password there, as well. Consider using a password manager such as LastPass or 1Password, which make creating and using complex and unique passwords easy no matter where you’re trying to sign in.

Approaches to Backing Up Your Cryptocurrency Keys

There are numerous ways to be sure your keys are backed up. Let’s take them one by one.

1. Automatic backups using a backup program

If you’re using a wallet program on your computer, for example, Bitcoin Core, it will store your keys, along with other information, in a file. For Bitcoin Core, that file is wallet.dat. Other currencies will use the same or a different file name and some give you the option to select a name for the wallet file.

To back up the wallet.dat or other wallet file, you might need to tell your backup program to explicitly back up that file. Users of Backblaze Backup don’t have to worry about configuring this, since by default, Backblaze Backup will back up all data files. You should determine where your particular cryptocurrency, wallet, or application stores your keys, and make sure the necessary file(s) are backed up if your backup program requires you to select which files are included in the backup.

Backblaze B2 is an option for those interested in low-cost and high security cloud storage of their cryptocurrency keys. Backblaze B2 supports 2-factor verification for account access, works with a number of apps that support automatic backups with encryption, error-recovery, and versioning, and offers an API and command-line interface (CLI), as well. The first 10GB of storage is free, which could be all one needs to store encrypted cryptocurrency keys.

2. Backing up by exporting keys to a file

Apps and wallets will let you export your keys from your app or wallet to a file. Once exported, your keys can be stored on a local drive, USB thumb drive, DAS, NAS, or in the cloud with any cloud storage or sync service you wish. Encrypting the file is strongly encouraged — more on that later. If you use 1Password or LastPass, or other secure notes program, you also could store your keys there.

3. Backing up by saving a mnemonic recovery seed

A mnemonic phrase, mnemonic recovery phrase, or mnemonic seed is a list of words that stores all the information needed to recover a cryptocurrency wallet. Many wallets will have the option to generate a mnemonic backup phrase, which can be written down on paper. If the user’s computer no longer works or their hard drive becomes corrupted, they can download the same wallet software again and use the mnemonic recovery phrase to restore their keys.

The phrase can be used by anyone to recover the keys, so it must be kept safe. Mnemonic phrases are an excellent way of backing up and storing cryptocurrency and so they are used by almost all wallets.

A mnemonic recovery seed is represented by a group of easy to remember words. For example:

eye female unfair moon genius pipe nuclear width dizzy forum cricket know expire purse laptop scale identify cube pause crucial day cigar noise receive

The above words represent the following seed:

0a5b25e1dab6039d22cd57469744499863962daba9d2844243fec 9c0313c1448d1a0b2cd9e230a78775556f9b514a8be45802c2808e fd449a20234e9262dfa69

These words have certain properties:

  • The first four letters are enough to unambiguously identify the word.
  • Similar words are avoided (such as: build and built).

Bitcoin and most other cryptocurrencies such as Litecoin, Ethereum, and others use mnemonic seeds that are 12 to 24 words long. Other currencies might use different length seeds.

4. Physical backups — Paper, Metal

Some cryptocurrency holders believe that their backup, or even all their cryptocurrency account information, should be stored entirely separately from the internet to avoid any risk of their information being compromised through hacks, exploits, or leaks. This type of storage is called “cold storage.” One method of cold storage involves printing out the keys to a piece of paper and then erasing any record of the keys from all computer systems. The keys can be entered into a program from the paper when needed, or scanned from a QR code printed on the paper.

Printed public and private keys

Printed public and private keys

Some who go to extremes suggest separating the mnemonic needed to access an account into individual pieces of paper and storing those pieces in different locations in the home or office, or even different geographical locations. Some say this is a bad idea since it could be possible to reconstruct the mnemonic from one or more pieces. How diligent you wish to be in protecting these codes is up to you.

Mnemonic recovery phrase booklet

Mnemonic recovery phrase booklet

There’s another option that could make you the envy of your friends. That’s the CryptoSteel wallet, which is a stainless steel metal case that comes with more than 250 stainless steel letter tiles engraved on each side. Codes and passwords are assembled manually from the supplied part-randomized set of tiles. Users are able to store up to 96 characters worth of confidential information. Cryptosteel claims to be fireproof, waterproof, and shock-proof.

image of a Cryptosteel cold storage device

Cryptosteel cold wallet

Of course, if you leave your Cryptosteel wallet in the pocket of a pair of ripped jeans that gets thrown out by the housekeeper, as happened to the character Russ Hanneman on the TV show Silicon Valley in last Sunday’s episode, then you’re out of luck. That fictional billionaire investor lost a USB drive with $300 million in cryptocoins. Let’s hope that doesn’t happen to you.

Encryption & Security

Whether you store your keys on your computer, an external disk, a USB drive, DAS, NAS, or in the cloud, you want to make sure that no one else can use those keys. The best way to handle that is to encrypt the backup.

With Backblaze Backup for Windows and Macintosh, your backups are encrypted in transmission to the cloud and on the backup server. Users have the option to add an additional level of security by adding a Personal Encryption Key (PEK), which secures their private key. Your cryptocurrency backup files are secure in the cloud. Using our web or mobile interface, previous versions of files can be accessed, as well.

Our object storage cloud offering, Backblaze B2, can be used with a variety of applications for Windows, Macintosh, and Linux. With B2, cryptocurrency users can choose whichever method of encryption they wish to use on their local computers and then upload their encrypted currency keys to the cloud. Depending on the client used, versioning and life-cycle rules can be applied to the stored files.

Other backup programs and systems provide some or all of these capabilities, as well. If you are backing up to a local drive, it is a good idea to encrypt the local backup, which is an option in some backup programs.

Address Security

Some experts recommend using a different address for each cryptocurrency transaction. Since the address is not the same as your wallet, this means that you are not creating a new wallet, but simply using a new identifier for people sending you cryptocurrency. Creating a new address is usually as easy as clicking a button in the wallet.

One of the chief advantages of using a different address for each transaction is anonymity. Each time you use an address, you put more information into the public ledger (blockchain) about where the currency came from or where it went. That means that over time, using the same address repeatedly could mean that someone could map your relationships, transactions, and incoming funds. The more you use that address, the more information someone can learn about you. For more on this topic, refer to Address reuse.

Note that a downside of using a paper wallet with a single key pair (type-0 non-deterministic wallet) is that it has the vulnerabilities listed above. Each transaction using that paper wallet will add to the public record of transactions associated with that address. Newer wallets, i.e. “deterministic” or those using mnemonic code words support multiple addresses and are now recommended.

There are other approaches to keeping your cryptocurrency transaction secure. Here are a couple of them.

Multi-signature

Multi-signature refers to requiring more than one key to authorize a transaction, much like requiring more than one key to open a safe. It is generally used to divide up responsibility for possession of cryptocurrency. Standard transactions could be called “single-signature transactions” because transfers require only one signature — from the owner of the private key associated with the currency address (public key). Some wallets and apps can be configured to require more than one signature, which means that a group of people, businesses, or other entities all must agree to trade in the cryptocurrencies.

Deep Cold Storage

Deep cold storage ensures the entire transaction process happens in an offline environment. There are typically three elements to deep cold storage.

First, the wallet and private key are generated offline, and the signing of transactions happens on a system not connected to the internet in any manner. This ensures it’s never exposed to a potentially compromised system or connection.

Second, details are secured with encryption to ensure that even if the wallet file ends up in the wrong hands, the information is protected.

Third, storage of the encrypted wallet file or paper wallet is generally at a location or facility that has restricted access, such as a safety deposit box at a bank.

Deep cold storage is used to safeguard a large individual cryptocurrency portfolio held for the long term, or for trustees holding cryptocurrency on behalf of others, and is possibly the safest method to ensure a crypto investment remains secure.

Keep Your Software Up to Date

You should always make sure that you are using the latest version of your app or wallet software, which includes important stability and security fixes. Installing updates for all other software on your computer or mobile device is also important to keep your wallet environment safer.

One Last Thing: Think About Your Testament

Your cryptocurrency funds can be lost forever if you don’t have a backup plan for your peers and family. If the location of your wallets or your passwords is not known by anyone when you are gone, there is no hope that your funds will ever be recovered. Taking a bit of time on these matters can make a huge difference.

To the Moon*

Are you comfortable with how you’re managing and backing up your cryptocurrency wallets and keys? Do you have a suggestion for keeping your cryptocurrencies safe that we missed above? Please let us know in the comments.


*To the Moon — Crypto slang for a currency that reaches an optimistic price projection.

The post Securing Your Cryptocurrency appeared first on Backblaze Blog | Cloud Storage & Cloud Backup.

Supply-Chain Security

Post Syndicated from Bruce Schneier original https://www.schneier.com/blog/archives/2018/05/supply-chain_se.html

Earlier this month, the Pentagon stopped selling phones made by the Chinese companies ZTE and Huawei on military bases because they might be used to spy on their users.

It’s a legitimate fear, and perhaps a prudent action. But it’s just one instance of the much larger issue of securing our supply chains.

All of our computerized systems are deeply international, and we have no choice but to trust the companies and governments that touch those systems. And while we can ban a few specific products, services or companies, no country can isolate itself from potential foreign interference.

In this specific case, the Pentagon is concerned that the Chinese government demanded that ZTE and Huawei add “backdoors” to their phones that could be surreptitiously turned on by government spies or cause them to fail during some future political conflict. This tampering is possible because the software in these phones is incredibly complex. It’s relatively easy for programmers to hide these capabilities, and correspondingly difficult to detect them.

This isn’t the first time the United States has taken action against foreign software suspected to contain hidden features that can be used against us. Last December, President Trump signed into law a bill banning software from the Russian company Kaspersky from being used within the US government. In 2012, the focus was on Chinese-made Internet routers. Then, the House Intelligence Committee concluded: “Based on available classified and unclassified information, Huawei and ZTE cannot be trusted to be free of foreign state influence and thus pose a security threat to the United States and to our systems.”

Nor is the United States the only country worried about these threats. In 2014, China reportedly banned antivirus products from both Kaspersky and the US company Symantec, based on similar fears. In 2017, the Indian government identified 42 smartphone apps that China subverted. Back in 1997, the Israeli company Check Point was dogged by rumors that its government added backdoors into its products; other of that country’s tech companies have been suspected of the same thing. Even al-Qaeda was concerned; ten years ago, a sympathizer released the encryption software Mujahedeen Secrets, claimed to be free of Western influence and backdoors. If a country doesn’t trust another country, then it can’t trust that country’s computer products.

But this trust isn’t limited to the country where the company is based. We have to trust the country where the software is written — and the countries where all the components are manufactured. In 2016, researchers discovered that many different models of cheap Android phones were sending information back to China. The phones might be American-made, but the software was from China. In 2016, researchers demonstrated an even more devious technique, where a backdoor could be added at the computer chip level in the factory that made the chips ­ without the knowledge of, and undetectable by, the engineers who designed the chips in the first place. Pretty much every US technology company manufactures its hardware in countries such as Malaysia, Indonesia, China and Taiwan.

We also have to trust the programmers. Today’s large software programs are written by teams of hundreds of programmers scattered around the globe. Backdoors, put there by we-have-no-idea-who, have been discovered in Juniper firewalls and D-Link routers, both of which are US companies. In 2003, someone almost slipped a very clever backdoor into Linux. Think of how many countries’ citizens are writing software for Apple or Microsoft or Google.

We can go even farther down the rabbit hole. We have to trust the distribution systems for our hardware and software. Documents disclosed by Edward Snowden showed the National Security Agency installing backdoors into Cisco routers being shipped to the Syrian telephone company. There are fake apps in the Google Play store that eavesdrop on you. Russian hackers subverted the update mechanism of a popular brand of Ukrainian accounting software to spread the NotPetya malware.

In 2017, researchers demonstrated that a smartphone can be subverted by installing a malicious replacement screen.

I could go on. Supply-chain security is an incredibly complex problem. US-only design and manufacturing isn’t an option; the tech world is far too internationally interdependent for that. We can’t trust anyone, yet we have no choice but to trust everyone. Our phones, computers, software and cloud systems are touched by citizens of dozens of different countries, any one of whom could subvert them at the demand of their government. And just as Russia is penetrating the US power grid so they have that capability in the event of hostilities, many countries are almost certainly doing the same thing at the consumer level.

We don’t know whether the risk of Huawei and ZTE equipment is great enough to warrant the ban. We don’t know what classified intelligence the United States has, and what it implies. But we do know that this is just a minor fix for a much larger problem. It’s doubtful that this ban will have any real effect. Members of the military, and everyone else, can still buy the phones. They just can’t buy them on US military bases. And while the US might block the occasional merger or acquisition, or ban the occasional hardware or software product, we’re largely ignoring that larger issue. Solving it borders on somewhere between incredibly expensive and realistically impossible.

Perhaps someday, global norms and international treaties will render this sort of device-level tampering off-limits. But until then, all we can do is hope that this particular arms race doesn’t get too far out of control.

This essay previously appeared in the Washington Post.