Secure your indirect dependencies with Snyk
Snyk Open Source finds and fixes vulnerabilities in both direct and indirect dependencies.
This report explores the adoption of security tools, practices, and technologies and the impact of automation and artificial intelligence (AI) in software development.
Part one
The more frequently code is changed, the greater the risks of supply chain vulnerabilities and the faster patches must be applied. We found that 80% of organizations are shipping code daily or weekly, likely indicating a shift towards more modular code architectures built on open source applications and libraries which require constant updates due to their complexities and dependency structures. Our survey found that 66% of organizations can remediate critical open source vulnerabilities within a day, and 27% within a few hours. There remains room for improvement as only 27% of organizations continuously audit code for vulnerabilities and another 28% audit code daily. Continuous or high-frequency audits improve safety due to the increasing number of zero-day vulnerabilities.
Daily
134
Weekly
199
Monthly
53
Quarterly
14
DK
4
Despite cyber attacks hitting records year over year and an increasing number of attacks focusing on open source code, a high percentage of responding organizations still don’t use the two most fundamental supply chain security technologies — software composition analysis (SCA, for open source dependencies) and static application security testing (SAST, for non-public implementations of open source code and proprietary code). Cloud native security measures, like configuration checks for infrastructure as code tools and secrets scanning, are adopted by even fewer.
300
200
100
0
0
100
200
300
Software Composition Analysis (SCA)
Static Code Analysis / Static Applications Security Testing (SAST)
Automated Package Management
Dependency Analysis
License Scanning
Secrets Management
Configuration Checks
None of the above
Software Composition Analysis (SCA)
Static Code Analysis / Static Applications Security Testing (SAST)
Automated Package Management
Dependency Analysis
License Scanning
Secrets Management
Configuration Checks
None of the above
Checking the security posture of open source packages is critical for maintaining software supply chain security and automated systems to check that packages follow security best practices, such as Snyk Advisor or OpenSSF Scorecard, are the most reliable way to programmatically analyze risk. These systems, however, are the least popular methods for checking the safety of open source packages. Only 40% of respondents use Snyk Advisor and only 34% use security scorecards.
Surprisingly, only 52% of respondents verify that all packages have a “responsible disclosures” policy — which should be table stakes for any package that’s being used.
300
200
100
0
0
100
200
300
I use the information in the registry or package manager
I use a tool like Snyk Advisor
I look at repository ratings or package downloads statistics
I look at the frequency of releases/commits/etc.
I check that the project has an active community
I check that the project has a responsible disclosure policy (such as a SECURITY.md)
I check the security scorecard
I don’t check the safety of open source packages.
I use the information in the registry or package manager
I use a tool like Snyk Advisor
I look at repository ratings or package downloads statistics
I look at the frequency of releases/commits/etc.
I check that the project has an active community
I check that the project has a responsible disclosure policy (such as a SECURITY.md)
I check the security scorecard
I don’t check the safety of open source packages.
A critical challenge in open source security is monitoring dependencies of third-party open source packages and libraries. Organizations clearly recognize that dependency tracking is critical to security, with 67% of organizations using a tool like Snyk to track direct and indirect dependencies. Another 25% track direct dependencies only. Tracking indirect dependencies produces a more holistic and accurate view of the entire attack surface, often surfacing hidden supply chain security weaknesses. These weaknesses often cannot be easily remedied due to the fact that nested dependencies are embedded in open source packages and libraries maintained by parties with at least one degree of separation from the direct dependency.
No
23
Direct Only
103
Direct + Indirect
270
Not Sure
8
Shifting security to the left has been a priority for many engineering organizations seeking to proactively improve code security and reduce vulnerabilities that are inadvertently inserted into code during software development. This improves speed and efficiency in the SDLC as fewer builds are blocked in pre-deployment testing and routed back to developers to fix. Shifting left also remains unfinished business as only 40% of respondents indicated that their organization deploys security tooling into IDEs, with an even smaller percentage using them locally on the command line. The most common locations for security tooling are in build tools and code repositories, both around 65%.
300
200
100
0
0
100
200
300
IDE
CLI
Build system
Pre-Commit Checks
Code Repository
CI/CD pipeline
Don't know
IDE
CLI
Build system
Pre-Commit Checks
Code Repository
CI/CD pipeline
Don't know
Snyk Open Source finds and fixes vulnerabilities in both direct and indirect dependencies.
Part Two
The responses to the survey indicate that the software supply chain security crisis is real and impacting organizations in a variety of ways. The strong majority of respondents were impacted by one or more supply chain issues within the past year. Regarding specific impacts, 53% had to patch one or more vulnerabilities, and 61% implemented new tooling and best practices for open source and supply chain security, indicating that many are taking action only after the impacts of a supply chain attack affect them directly.
250
200
150
100
50
0
0
50
100
150
200
250
We had to patch one or more supply chain vulnerabilities
We implemented new tooling and practices to better handle supply chain vulnerabilities
We trained our development team to help them better understand supply chain vulnerabilities
We have not been impacted by open source software supply chain vulnerabilities in the past year
We had to patch one or more supply chain vulnerabilities
We implemented new tooling and practices to better handle supply chain vulnerabilities
We trained our development team to help them better understand supply chain vulnerabilities
We have not been impacted by open source software supply chain vulnerabilities in the past year
This mirrored the overall response to Log4Shell, where clearly organizations are responding with significant changes. In response to the incident, 63% of respondents said their organization’s increased code scan frequency, 59% added new tooling, and 53% gave dev teams additional training on secure coding practices. Log4Shell also appeared to improve the security hygeine of most organizations — 58% of respondents said they applied required patches more quickly, motivated by Log4Shell. While the incident may have caused short-term chaos as organizations frantically sought to identify and patch nested exposures, the longer-term impact appears to be beneficial — teams have upped their security game at least in part as a direct response to the incident.
300
200
100
0
0
100
200
300
Increased code scan frequency
Gave development teams additional training
Applied patches more quickly
Added new security tooling
None of the above
Increased code scan frequency
Gave development teams additional training
Applied patches more quickly
Added new security tooling
None of the above
Actual adoption of software supply chain security best practices appears scattered and only 53% of organizations have a formal supply chain security program. This could be because software supply chain security is considered a subset of the general security practice, but it does beg the question of whether supply chain security has yet become a burning issue for organizations (or enough of a burning issue to merit a program-level view and plan). In terms of more specific practices, only 42% of organizations are using SBOMs, 58%, are implementing code signing for attribution of code, and 62%, are adopting a software lifecycle assurance process (such as SLSA).
300
200
100
0
0
100
200
300
Formal software supply chain security program
SBOMs
SLSA
Code signing
Regular Audits
None of the above
Formal software supply chain security program
SBOMs
SLSA
Code signing
Regular Audits
None of the above
Clearly, the message that SBOMs are a useful tool is getting through to engineering and security teams. 42% of respondents are already using SBOMs, and 31% plan to adopt them in the near future, forecasting impressive growth. That said, respondents said they are generating SBOMs from various software development and CI/CD tools, as well as from dedicated supply chain security systems. This may be due to the relative fragmentation in the SBOM technology space. There remain two dueling standards (Cyclone, SPDX) with no accepted standards for interoperability. This likely indicates fragmentation and disconnection in the space — an SBOM tower of Babel. While SBOMs are primarily generated by code scanning and security tools (68%), other common systems used to generate SBOMs include build tools (58%), CI/CD tools (45%), and dedicated supply chain security tools ((53%)
300
200
100
0
0
100
200
300
CI/CD tools
Build tools
Code scanning and security tools
Dedicated supply chain security tool
None of the above
CI/CD tools
Build tools
Code scanning and security tools
Dedicated supply chain security tool
None of the above
87% of our respondents were impacted by supply chain security issues. Keep yours secure with Snyk.
Part Three
AI code-generating tools have achieved blanket penetration and are now being deployed by 92% of organizations. 76.5% of respondents believe that these tools have improved their organization’s code security. Only 14.9% of respondents said the AI tools had introduced “a lot” of vulnerabilities into their code. In contrast, 73% said AI had introduced “very few” or “a moderate amount” of vulnerabilities into their code. Yet, 59% of respondents said they are concerned that AI tools will introduce security vulnerabilities into their code, and 50% are concerned AI will introduce licensing violations into their code. In a nutshell, developers believe AI is improving their code security without introducing a lot of new vulnerabilities, but they remain skeptical of these newer systems.
Very few
132
A moderate amount
165
A lot
56
None
15
Don’t know
9
Not Applicable
27
A high percentage of organizations are automating some or all of their security measures in the code pipeline. 64% of organizations have automated code analysis, 61% have automated software update management, 59% have automated testing (unit, security), 58% have automated secure coding practices (linters, formatting, etc.), and nearly half have automated container and infrastructure configuration scanning. Respondents indicated that automated security tooling has considerably increased the rate of false positives in vulnerability reports, with 60% stating automation had increased false positives versus 30% saying automation had decreased false positives.
Increased
246
Decreased
121
Don’t know
22
NA – We don’t use automation
15
The percentage of false positives was non-trivial. 62% of respondents said that 25% or more of vulnerability alerts they received were false positives, and 35% said false positives represented 50% or more of vulnerability alerts. This high rate of false positives likely contributes to on the surface would seem to be a surprisingly low vulnerability fix rate.
0-25%
139
26-50%
110
51-75%
93
76% - 100%
47
Don’t know
15
Snyk DeepCode AI utilizes multiple AI models trained on security-specific data with curation from top security researchers to give you all the power of AI without the drawbacks.
Part Four
For this analysis, we considered vulnerabilities that at least 20 organizations had chosen to ignore (based on Snyk data). With a vast ecosystem of legacy code and a packaging system (.jar files) that frequently obfuscates vulnerabilities and dependencies, it’s no surprise that Java has the largest percentage of ignored vulnerabilities at 42.5%. JavaScript, with its numerous packages – many for minute functions and functionalities – is understandably second, with 30.6% of ignored vulnerabilities. Debian, the Linux distribution family, takes a distant third, at 13.6%. If anything, this distribution understates the attack surface because Java and JavaScript also dominate not just by count but also in weighting. The top 34 ignored vulnerabilities in terms of the number of organizations ignoring these vulnerabilities are all Java and Javascript.
debian
13.6%
alpine
0.5%
golang
3.8%
python
6.6%
js
30.6%
java
42.5%
ruby
0.2%
ubuntu
0.5%
dot.net
1.7%
The type of vulnerabilities ignored by organizations provides useful information on attack surface and risks that are accepted, either consciously or subconsciously. By far, the dominant type of threat among the CVEs ignored by at least 50 accounts were flavors of denial of service (DoS). These vulnerabilities made up 31.3% of all ignored vulnerabilities. While serious, DoS attacks are often proactively mitigated at the CDN or infrastructure level, so many teams understandably deprioritize these CVEs. Deserialization of untrusted data made up 14.3% of CVEs ignored by over 50 accounts. This is a relatively broad class of vulnerabilities potentially impacting multiple languages. This can often be the first step in chained or compound attacks, making it a serious vulnerability. The third most common, prototype pollution (at 12.5%), mostly impacts the JavaScript community.
Remote Code Execution
3.6%
Denial of Service (DoS)
14.3%
Deserialization of Untrusted Data
14.3%
Prototype Pollution
12.5%
Information Exposure
7.1%
Regular Expression Denial of Service (ReDoS)
17%
Directory Traversal
2.7%
Improper Verification of Cryptographic Signature
2.7%
Arbitrary File Write
4.5%
Other
21.3%
Part Five
Since the dawn of open source, the argument has raged about whether open source software is, in fact, more secure than closed source software. Vulnerabilities are published and in the open, as are the accompanying fixes. So it is possible to track data on time-to-fix (TTF) using vulnerability databases. We tracked TTF over the past four complete calendar years and found that the average TTF has steadily increased for proprietary applications and steadily decreased for open source applications since 2019. To be fair, both genres reduced TTF in 2021, but for the first time since we have tracked this metric, TTF for open source applications fell below TTF for proprietary applications. This implies the open source ecosystem is improving security response over time and trending towards providing better security than the closed source world.
Open Source
Proprietary
300
200
100
0
0
100
200
300
2019
2020
2021
2022
After witnessing a major spike in TTF average of critical and high-priority vulnerabilities, for the past two years has fallen dramatically. This spike could be an indication that open source scanning had increased in those years, shining a light on vulnerabilities that had previously been unseen. From 2021 to 2022, the average TTF for those two critical designations fell roughly by half, -51% for critical and -49.4% for high-priority vulnerabilities. There could be a number of explanations for this steady decline, including wider adoption of open source security tooling such as SCA, more funding and personnel going towards fixing critical open source vulnerabilities, and greater recognition in open source projects that security is a top priority. Regardless, the signs are good and trending strongly in the right direction for continued improvement in OSS security.
Critical
High
Medium
Low
1,500
1,000
500
0
0
500
1,000
1,500
2018
2019
2020
2021
2022
The TTF did vary across open source ecosystems and declined markedly for the majority of major open source ecosystems tracked by Snyk. The greatest declines in average TTF were in Java and Python, at 50.8% and 43.4%, respectively. All five of the ecosystems that recorded declines did manage double-digit reductions. The largest total decline in terms of days was in Go and Python, with Go logging a 147-day reduction in average TTF and Python notching a 115-day reduction. Two ecosystems did regress. The C and Ruby ecosystems showed a 144.7% and 102.1% increase in average days TTF, with total days increasing by 55 and 49 for the respective ecosystems. Open source ecosystems are improving security response times and, by extension, strengthening supply chain security by shortening the window between publication and remediation of vulnerabilities.
2021 to 22
2022 to 2023
400
300
200
100
0
0
100
200
300
400
cpp
dotnet
go
js
java
php
python
ruby
Conclusion
Over the past few years, technology organizations have made great strides in improving open source and supply chain security. They have learned the lessons of Log4Shell and made adjustments — including more tooling, more training, and greater scan frequency. On the flip side, there remains considerable room for improvement in open source security. Concerningly high percentages of organizations are still not using foundational security technologies like SCA and SAST. Open source security has clearly come a long way, and we are, in the aggregate, more secure as a community than before. Much progress has been made, but there remains much room for improvement — in the adoption of supply chain security technologies, new and mature, in reducing the workload and improving prioritization for stressed security teams, and in making supply chain security a core foundation of the software development lifecycle process.
Read Snyk’s full report on the state of open source security in 2023 for a deeper dive into the risks caused by ignored issues and SBOM confusion and discover strong improvements made for encouraging progress in OSS.
Snyk is a developer security platform. Integrating directly into development tools, workflows, and automation pipelines, Snyk makes it easy for teams to find, prioritize, and fix security vulnerabilities in code, dependencies, containers, and infrastructure as code. Supported by industry-leading application and security intelligence, Snyk puts security expertise in any developer’s toolkit.
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