Comparison Overview
Ingersoll Rand Pumps

Ingersoll Rand Pumps
12500 S Pulaski Rd, Alsip, 60803, US
Last Update: 30/01/2026
Ingersoll Rand pumps is known for engineering design and expertise providing reliable pump solutions in the most difficult applications. Ingersoll Rand pumps provide industry leading solutions for precise and accurate flow for metering and dosing as well as lubrication ...

ANDRITZ
Stattegger Strasse 18, Graz, 8045, AT
Last Update: 01/04/2026
ANDRITZ is an international technology group based in Austria. The company offers a broad portfolio of innovative plants, equipment, systems, services and digital solutions for a wide range of industries and end markets. Sustainability is an integral part of the compa...
Compliance Ranges Comparison

Ingersoll Rand Pumps







ANDRITZ






Benchmark & Cyber Underwriting Signals
Incidents vs Machinery Manufacturing Industry Avg (This Year)
No incidents recorded for Ingersoll Rand Pumps in 2026.
Incidents vs Machinery Manufacturing Industry Avg (This Year)
No incidents recorded for ANDRITZ in 2026.
Incident History - Ingersoll Rand Pumps (X = Date, Y = Severity)
Ingersoll Rand Pumps cyber incidents detection timeline including parent company and subsidiaries.
Incident History - ANDRITZ (X = Date, Y = Severity)
ANDRITZ cyber incidents detection timeline including parent company and subsidiaries.
Notable Incidents

Ingersoll Rand Pumps

ANDRITZ
FAQ
Latest Global CVEs
h2o is an HTTP server with support for HTTP/1.x, HTTP/2 and HTTP/3. Prior to commit 6b5370d, h2o is vulnerable to a Denial of Service attack when calling alloca under certain conditions. When serving static files, h2o builds the file path on stack, by calling alloca. The maximum size of the memory allocated using alloca can be as huge as ~600KB, which exceeds the default pthread stack size used by musl libc (128KB). If the amount of memory allocated by alloca exceeds the stack size, the h2o server crashes with a segmentation fault, while it tries to touch the guard page. This issue has been fixed by commit 6b5370d.
h2o is an HTTP server with support for HTTP/1.x, HTTP/2 and HTTP/3. Prior to commit 8dc37cb, when h2o receives a ClientHello message over TLS or QUIC and it contains a zero-length SNI extension, the h2o server runs over the zero-length hostname while trying to copy the hostname, assuming that it is NULL-terminated. This is a potential denial-of-service attack vector in sense that it might trigger segmentation violation. This issue has been fixed by commit 8dc37cb.
Quicly is an IETF QUIC protocol implementation intended primarily for use within the H2O HTTP server. Prior to commit 8b178e6, Quicly is vulnerable to a Denial of Service attack through connection state corruption. In QUIC Invariants, the maximum length of a Connection ID is 255 bytes, while QUIC version 1 further restricts the maximum to 20 bytes. Quicly implements QUIC version 1 and therefore its CID buffers are limited to 20 bytes. However, to be able to respond to unknown versions of QUIC, its packet decoder accepts Connection IDs of up to 255 bytes. As its CID buffers are merely 20 bytes long, Quicly must reject QUIC version 1 packets with Connection IDs longer than that. The command line tool bundled with Quicly has had that check, however the library itself lacked such enforcement. As a consequence, when used by applications that lack their own enforcement, the connection state becoming inconsistent to buffer overrun. Fortunately, the overflow stops within the allocated chunk of memory, but nevertheless, the bug leads to assertion failures. This issue has been fixed by commit 8b178e6.
Quicly is an IETF QUIC protocol implementation intended primarily for use within the H2O HTTP server. Prior to commit 937d0e9, an assertion failure is raised when the total number of valid handshake messages received over a CRYPTO stream of a single packet number space exceeds 32KB, causing a Denial of Service. This issue has been fixed by commit 937d0e9.
Quicly is an IETF QUIC protocol implementation intended primarily for use within the H2O HTTP server. Prior to commit dccf5d4, Quicly was vulnerable to stateless reset injection through lack of packet entry validation. The QUIC protocol is designed to withstand packet injection attacks, once the handshake is complete. Only packets that carry some secret patterns are considered as stateless resets. Quicly allows the peer to share up to 4 such patterns per connection. However, until now, it failed to determine which of the 4 slots that it uses to retain the secret patterns contains a valid entry. As the slots are zero-initialized, the failure meant that, unless the peer advertised 4 of such patterns, an all-zero pattern was treated as a stateless reset.In effect, this allowed an on-path attacker to reset QUIC connections governed by Quicly. This issue has been fixed by commit dccf5d4.