Search for packages
| purl | pkg:openssl/openssl@1.0.2f |
| Next non-vulnerable version | 1.0.2zc-de |
| Latest non-vulnerable version | 3.0.7 |
| Risk | 10.0 |
| Vulnerability | Summary | Fixed by |
|---|---|---|
|
VCID-1gxv-1j1x-aaag
Aliases: CVE-2019-1547 VC-OPENSSL-20190910-CVE-2019-1547 |
Normally in OpenSSL EC groups always have a co-factor present and this is used in side channel resistant code paths. However, in some cases, it is possible to construct a group using explicit parameters (instead of using a named curve). In those cases it is possible that such a group does not have the cofactor present. This can occur even where all the parameters match a known named curve. If such a curve is used then OpenSSL falls back to non-side channel resistant code paths which may result in full key recovery during an ECDSA signature operation. In order to be vulnerable an attacker would have to have the ability to time the creation of a large number of signatures where explicit parameters with no co-factor present are in use by an application using libcrypto. For the avoidance of doubt libssl is not vulnerable because explicit parameters are never used. Fixed in OpenSSL 1.1.1d (Affected 1.1.1-1.1.1c). Fixed in OpenSSL 1.1.0l (Affected 1.1.0-1.1.0k). Fixed in OpenSSL 1.0.2t (Affected 1.0.2-1.0.2s). |
Affected by 11 other vulnerabilities. Affected by 0 other vulnerabilities. Affected by 13 other vulnerabilities. |
|
VCID-42tc-p92q-aaap
Aliases: CVE-2016-2105 VC-OPENSSL-20160503-CVE-2016-2105 |
Integer overflow in the EVP_EncodeUpdate function in crypto/evp/encode.c in OpenSSL before 1.0.1t and 1.0.2 before 1.0.2h allows remote attackers to cause a denial of service (heap memory corruption) via a large amount of binary data. |
Affected by 37 other vulnerabilities. |
|
VCID-4hq6-j84v-aaan
Aliases: CVE-2017-3738 VC-OPENSSL-20171207-CVE-2017-3738 |
There is an overflow bug in the AVX2 Montgomery multiplication procedure used in exponentiation with 1024-bit moduli. No EC algorithms are affected. Analysis suggests that attacks against RSA and DSA as a result of this defect would be very difficult to perform and are not believed likely. Attacks against DH1024 are considered just feasible, because most of the work necessary to deduce information about a private key may be performed offline. The amount of resources required for such an attack would be significant. However, for an attack on TLS to be meaningful, the server would have to share the DH1024 private key among multiple clients, which is no longer an option since CVE-2016-0701. This only affects processors that support the AVX2 but not ADX extensions like Intel Haswell (4th generation). Note: The impact from this issue is similar to CVE-2017-3736, CVE-2017-3732 and CVE-2015-3193. OpenSSL version 1.0.2-1.0.2m and 1.1.0-1.1.0g are affected. Fixed in OpenSSL 1.0.2n. Due to the low severity of this issue we are not issuing a new release of OpenSSL 1.1.0 at this time. The fix will be included in OpenSSL 1.1.0h when it becomes available. The fix is also available in commit e502cc86d in the OpenSSL git repository. |
Affected by 19 other vulnerabilities. Affected by 9 other vulnerabilities. |
|
VCID-581z-anfk-aaaq
Aliases: CVE-2016-6302 VC-OPENSSL-20160823-CVE-2016-6302 |
The tls_decrypt_ticket function in ssl/t1_lib.c in OpenSSL before 1.1.0 does not consider the HMAC size during validation of the ticket length, which allows remote attackers to cause a denial of service via a ticket that is too short. |
Affected by 27 other vulnerabilities. |
|
VCID-6pjh-cgdt-aaaj
Aliases: CVE-2022-0778 GHSA-x3mh-jvjw-3xwx VC-OPENSSL-20220315-CVE-2022-0778 |
The BN_mod_sqrt() function, which computes a modular square root, contains a bug that can cause it to loop forever for non-prime moduli. Internally this function is used when parsing certificates that contain elliptic curve public keys in compressed form or explicit elliptic curve parameters with a base point encoded in compressed form. It is possible to trigger the infinite loop by crafting a certificate that has invalid explicit curve parameters. Since certificate parsing happens prior to verification of the certificate signature, any process that parses an externally supplied certificate may thus be subject to a denial of service attack. The infinite loop can also be reached when parsing crafted private keys as they can contain explicit elliptic curve parameters. Thus vulnerable situations include: - TLS clients consuming server certificates - TLS servers consuming client certificates - Hosting providers taking certificates or private keys from customers - Certificate authorities parsing certification requests from subscribers - Anything else which parses ASN.1 elliptic curve parameters Also any other applications that use the BN_mod_sqrt() where the attacker can control the parameter values are vulnerable to this DoS issue. In the OpenSSL 1.0.2 version the public key is not parsed during initial parsing of the certificate which makes it slightly harder to trigger the infinite loop. However any operation which requires the public key from the certificate will trigger the infinite loop. In particular the attacker can use a self-signed certificate to trigger the loop during verification of the certificate signature. This issue affects OpenSSL versions 1.0.2, 1.1.1 and 3.0. It was addressed in the releases of 1.1.1n and 3.0.2 on the 15th March 2022. Fixed in OpenSSL 3.0.2 (Affected 3.0.0,3.0.1). Fixed in OpenSSL 1.1.1n (Affected 1.1.1-1.1.1m). Fixed in OpenSSL 1.0.2zd (Affected 1.0.2-1.0.2zc). |
Affected by 2 other vulnerabilities. Affected by 3 other vulnerabilities. Affected by 9 other vulnerabilities. |
|
VCID-9cyz-en38-aaad
Aliases: CVE-2018-0732 VC-OPENSSL-20180612-CVE-2018-0732 |
During key agreement in a TLS handshake using a DH(E) based ciphersuite a malicious server can send a very large prime value to the client. This will cause the client to spend an unreasonably long period of time generating a key for this prime resulting in a hang until the client has finished. This could be exploited in a Denial Of Service attack. Fixed in OpenSSL 1.1.0i-dev (Affected 1.1.0-1.1.0h). Fixed in OpenSSL 1.0.2p-dev (Affected 1.0.2-1.0.2o). |
Affected by 16 other vulnerabilities. Affected by 6 other vulnerabilities. |
|
VCID-9fjn-9378-aaae
Aliases: CVE-2016-2179 VC-OPENSSL-20160822-CVE-2016-2179 |
The DTLS implementation in OpenSSL before 1.1.0 does not properly restrict the lifetime of queue entries associated with unused out-of-order messages, which allows remote attackers to cause a denial of service (memory consumption) by maintaining many crafted DTLS sessions simultaneously, related to d1_lib.c, statem_dtls.c, statem_lib.c, and statem_srvr.c. |
Affected by 27 other vulnerabilities. |
|
VCID-9ruy-372r-aaas
Aliases: CVE-2021-23841 GHSA-84rm-qf37-fgc2 VC-OPENSSL-20210216-CVE-2021-23841 |
The OpenSSL public API function X509_issuer_and_serial_hash() attempts to create a unique hash value based on the issuer and serial number data contained within an X509 certificate. However it fails to correctly handle any errors that may occur while parsing the issuer field (which might occur if the issuer field is maliciously constructed). This may subsequently result in a NULL pointer deref and a crash leading to a potential denial of service attack. The function X509_issuer_and_serial_hash() is never directly called by OpenSSL itself so applications are only vulnerable if they use this function directly and they use it on certificates that may have been obtained from untrusted sources. OpenSSL versions 1.1.1i and below are affected by this issue. Users of these versions should upgrade to OpenSSL 1.1.1j. OpenSSL versions 1.0.2x and below are affected by this issue. However OpenSSL 1.0.2 is out of support and no longer receiving public updates. Premium support customers of OpenSSL 1.0.2 should upgrade to 1.0.2y. Other users should upgrade to 1.1.1j. Fixed in OpenSSL 1.1.1j (Affected 1.1.1-1.1.1i). Fixed in OpenSSL 1.0.2y (Affected 1.0.2-1.0.2x). |
Affected by 5 other vulnerabilities. Affected by 9 other vulnerabilities. |
|
VCID-9wtw-93e9-aaam
Aliases: CVE-2016-0799 VC-OPENSSL-20160301-CVE-2016-0799 |
The internal |fmtstr| function used in processing a "%s" format string in the BIO_*printf functions could overflow while calculating the length of a string and cause an OOB read when printing very long strings. Additionally the internal |doapr_outch| function can attempt to write to an OOB memory location (at an offset from the NULL pointer) in the event of a memory allocation failure. In 1.0.2 and below this could be caused where the size of a buffer to be allocated is greater than INT_MAX. E.g. this could be in processing a very long "%s" format string. Memory leaks can also occur. The first issue may mask the second issue dependent on compiler behaviour. These problems could enable attacks where large amounts of untrusted data is passed to the BIO_*printf functions. If applications use these functions in this way then they could be vulnerable. OpenSSL itself uses these functions when printing out human-readable dumps of ASN.1 data. Therefore applications that print this data could be vulnerable if the data is from untrusted sources. OpenSSL command line applications could also be vulnerable where they print out ASN.1 data, or if untrusted data is passed as command line arguments. Libssl is not considered directly vulnerable. Additionally certificates etc received via remote connections via libssl are also unlikely to be able to trigger these issues because of message size limits enforced within libssl. |
Affected by 42 other vulnerabilities. |
|
VCID-a12s-yyr4-aaad
Aliases: CVE-2016-2181 VC-OPENSSL-20160819-CVE-2016-2181 |
The Anti-Replay feature in the DTLS implementation in OpenSSL before 1.1.0 mishandles early use of a new epoch number in conjunction with a large sequence number, which allows remote attackers to cause a denial of service (false-positive packet drops) via spoofed DTLS records, related to rec_layer_d1.c and ssl3_record.c. |
Affected by 27 other vulnerabilities. |
|
VCID-agz8-77e4-aaaq
Aliases: CVE-2016-2182 VC-OPENSSL-20160816-CVE-2016-2182 |
The BN_bn2dec function in crypto/bn/bn_print.c in OpenSSL before 1.1.0 does not properly validate division results, which allows remote attackers to cause a denial of service (out-of-bounds write and application crash) or possibly have unspecified other impact via unknown vectors. |
Affected by 27 other vulnerabilities. |
|
VCID-bms1-jrax-aaap
Aliases: CVE-2016-6304 VC-OPENSSL-20160922-CVE-2016-6304 |
Multiple memory leaks in t1_lib.c in OpenSSL before 1.0.1u, 1.0.2 before 1.0.2i, and 1.1.0 before 1.1.0a allow remote attackers to cause a denial of service (memory consumption) via large OCSP Status Request extensions. |
Affected by 27 other vulnerabilities. Affected by 22 other vulnerabilities. |
|
VCID-ceua-4xhz-aaag
Aliases: CVE-2018-5407 VC-OPENSSL-20181102-CVE-2018-5407 |
Simultaneous Multi-threading (SMT) in processors can enable local users to exploit software vulnerable to timing attacks via a side-channel timing attack on 'port contention'. |
Affected by 14 other vulnerabilities. Affected by 6 other vulnerabilities. |
|
VCID-cg17-ah7e-aaag
Aliases: CVE-2016-2107 VC-OPENSSL-20160503-CVE-2016-2107 |
The AES-NI implementation in OpenSSL before 1.0.1t and 1.0.2 before 1.0.2h does not consider memory allocation during a certain padding check, which allows remote attackers to obtain sensitive cleartext information via a padding-oracle attack against an AES CBC session. NOTE: this vulnerability exists because of an incorrect fix for CVE-2013-0169. |
Affected by 37 other vulnerabilities. |
|
VCID-eg7n-8h8z-aaaa
Aliases: CVE-2016-6306 VC-OPENSSL-20160921-CVE-2016-6306 |
The certificate parser in OpenSSL before 1.0.1u and 1.0.2 before 1.0.2i might allow remote attackers to cause a denial of service (out-of-bounds read) via crafted certificate operations, related to s3_clnt.c and s3_srvr.c. |
Affected by 27 other vulnerabilities. |
|
VCID-egbc-ecck-aaag
Aliases: CVE-2016-2109 VC-OPENSSL-20160503-CVE-2016-2109 |
The asn1_d2i_read_bio function in crypto/asn1/a_d2i_fp.c in the ASN.1 BIO implementation in OpenSSL before 1.0.1t and 1.0.2 before 1.0.2h allows remote attackers to cause a denial of service (memory consumption) via a short invalid encoding. |
Affected by 37 other vulnerabilities. |
|
VCID-ejg3-awxf-aaan
Aliases: CVE-2016-0705 VC-OPENSSL-20160301-CVE-2016-0705 |
A double free bug was discovered when OpenSSL parses malformed DSA private keys and could lead to a DoS attack or memory corruption for applications that receive DSA private keys from untrusted sources. This scenario is considered rare. |
Affected by 42 other vulnerabilities. |
|
VCID-fmvb-j6br-aaap
Aliases: CVE-2018-0739 VC-OPENSSL-20180327-CVE-2018-0739 |
Constructed ASN.1 types with a recursive definition (such as can be found in PKCS7) could eventually exceed the stack given malicious input with excessive recursion. This could result in a Denial Of Service attack. There are no such structures used within SSL/TLS that come from untrusted sources so this is considered safe. Fixed in OpenSSL 1.1.0h (Affected 1.1.0-1.1.0g). Fixed in OpenSSL 1.0.2o (Affected 1.0.2b-1.0.2n). |
Affected by 18 other vulnerabilities. Affected by 9 other vulnerabilities. |
|
VCID-ghgs-7167-aaag
Aliases: CVE-2021-3712 GHSA-q9wj-f4qw-6vfj VC-OPENSSL-20210824-CVE-2021-3712 |
ASN.1 strings are represented internally within OpenSSL as an ASN1_STRING structure which contains a buffer holding the string data and a field holding the buffer length. This contrasts with normal C strings which are repesented as a buffer for the string data which is terminated with a NUL (0) byte. Although not a strict requirement, ASN.1 strings that are parsed using OpenSSL's own "d2i" functions (and other similar parsing functions) as well as any string whose value has been set with the ASN1_STRING_set() function will additionally NUL terminate the byte array in the ASN1_STRING structure. However, it is possible for applications to directly construct valid ASN1_STRING structures which do not NUL terminate the byte array by directly setting the "data" and "length" fields in the ASN1_STRING array. This can also happen by using the ASN1_STRING_set0() function. Numerous OpenSSL functions that print ASN.1 data have been found to assume that the ASN1_STRING byte array will be NUL terminated, even though this is not guaranteed for strings that have been directly constructed. Where an application requests an ASN.1 structure to be printed, and where that ASN.1 structure contains ASN1_STRINGs that have been directly constructed by the application without NUL terminating the "data" field, then a read buffer overrun can occur. The same thing can also occur during name constraints processing of certificates (for example if a certificate has been directly constructed by the application instead of loading it via the OpenSSL parsing functions, and the certificate contains non NUL terminated ASN1_STRING structures). It can also occur in the X509_get1_email(), X509_REQ_get1_email() and X509_get1_ocsp() functions. If a malicious actor can cause an application to directly construct an ASN1_STRING and then process it through one of the affected OpenSSL functions then this issue could be hit. This might result in a crash (causing a Denial of Service attack). It could also result in the disclosure of private memory contents (such as private keys, or sensitive plaintext). Fixed in OpenSSL 1.1.1l (Affected 1.1.1-1.1.1k). Fixed in OpenSSL 1.0.2za (Affected 1.0.2-1.0.2y). |
Affected by 4 other vulnerabilities. Affected by 5 other vulnerabilities. |
|
VCID-j8pb-xdpc-aaap
Aliases: CVE-2018-0737 VC-OPENSSL-20180416-CVE-2018-0737 |
The OpenSSL RSA Key generation algorithm has been shown to be vulnerable to a cache timing side channel attack. An attacker with sufficient access to mount cache timing attacks during the RSA key generation process could recover the private key. Fixed in OpenSSL 1.1.0i-dev (Affected 1.1.0-1.1.0h). Fixed in OpenSSL 1.0.2p-dev (Affected 1.0.2b-1.0.2o). |
Affected by 16 other vulnerabilities. Affected by 6 other vulnerabilities. |
|
VCID-jhg8-wbm2-aaas
Aliases: CVE-2017-3735 VC-OPENSSL-20170828-CVE-2017-3735 |
While parsing an IPAddressFamily extension in an X.509 certificate, it is possible to do a one-byte overread. This would result in an incorrect text display of the certificate. This bug has been present since 2006 and is present in all versions of OpenSSL before 1.0.2m and 1.1.0g. |
Affected by 21 other vulnerabilities. Affected by 12 other vulnerabilities. |
|
VCID-kryh-pfgh-aaag
Aliases: CVE-2016-2177 VC-OPENSSL-20160601-CVE-2016-2177 |
OpenSSL through 1.0.2h incorrectly uses pointer arithmetic for heap-buffer boundary checks, which might allow remote attackers to cause a denial of service (integer overflow and application crash) or possibly have unspecified other impact by leveraging unexpected malloc behavior, related to s3_srvr.c, ssl_sess.c, and t1_lib.c. |
Affected by 27 other vulnerabilities. |
|
VCID-m4nz-uw2e-aaaq
Aliases: CVE-2016-0798 VC-OPENSSL-20160301-CVE-2016-0798 |
The SRP user database lookup method SRP_VBASE_get_by_user had confusing memory management semantics; the returned pointer was sometimes newly allocated, and sometimes owned by the callee. The calling code has no way of distinguishing these two cases. Specifically, SRP servers that configure a secret seed to hide valid login information are vulnerable to a memory leak: an attacker connecting with an invalid username can cause a memory leak of around 300 bytes per connection. Servers that do not configure SRP, or configure SRP but do not configure a seed are not vulnerable. In Apache, the seed directive is known as SSLSRPUnknownUserSeed. To mitigate the memory leak, the seed handling in SRP_VBASE_get_by_user is now disabled even if the user has configured a seed. Applications are advised to migrate to SRP_VBASE_get1_by_user. However, note that OpenSSL makes no strong guarantees about the indistinguishability of valid and invalid logins. In particular, computations are currently not carried out in constant time. |
Affected by 42 other vulnerabilities. |
|
VCID-msmt-6x6r-aaaj
Aliases: CVE-2020-1968 VC-OPENSSL-20200909-CVE-2020-1968 |
The Raccoon attack exploits a flaw in the TLS specification which can lead to an attacker being able to compute the pre-master secret in connections which have used a Diffie-Hellman (DH) based ciphersuite. In such a case this would result in the attacker being able to eavesdrop on all encrypted communications sent over that TLS connection. The attack can only be exploited if an implementation re-uses a DH secret across multiple TLS connections. Note that this issue only impacts DH ciphersuites and not ECDH ciphersuites. This issue affects OpenSSL 1.0.2 which is out of support and no longer receiving public updates. OpenSSL 1.1.1 is not vulnerable to this issue. |
Affected by 9 other vulnerabilities. |
|
VCID-nx9u-49dk-aaag
Aliases: CVE-2020-1971 VC-OPENSSL-20201208-CVE-2020-1971 |
Affected by 8 other vulnerabilities. Affected by 11 other vulnerabilities. |
|
|
VCID-psvb-thr2-aaap
Aliases: CVE-2018-0734 VC-OPENSSL-20181030-CVE-2018-0734 |
The OpenSSL DSA signature algorithm has been shown to be vulnerable to a timing side channel attack. An attacker could use variations in the signing algorithm to recover the private key. Fixed in OpenSSL 1.1.1a (Affected 1.1.1). Fixed in OpenSSL 1.1.0j (Affected 1.1.0-1.1.0i). Fixed in OpenSSL 1.0.2q (Affected 1.0.2-1.0.2p). |
Affected by 14 other vulnerabilities. Affected by 4 other vulnerabilities. Affected by 17 other vulnerabilities. |
|
VCID-pzng-q94v-aaah
Aliases: CVE-2019-1552 VC-OPENSSL-20190730-CVE-2019-1552 |
OpenSSL has internal defaults for a directory tree where it can find a configuration file as well as certificates used for verification in TLS. This directory is most commonly referred to as OPENSSLDIR, and is configurable with the --prefix / --openssldir configuration options. For OpenSSL versions 1.1.0 and 1.1.1, the mingw configuration targets assume that resulting programs and libraries are installed in a Unix-like environment and the default prefix for program installation as well as for OPENSSLDIR should be '/usr/local'. However, mingw programs are Windows programs, and as such, find themselves looking at sub-directories of 'C:/usr/local', which may be world writable, which enables untrusted users to modify OpenSSL's default configuration, insert CA certificates, modify (or even replace) existing engine modules, etc. For OpenSSL 1.0.2, '/usr/local/ssl' is used as default for OPENSSLDIR on all Unix and Windows targets, including Visual C builds. However, some build instructions for the diverse Windows targets on 1.0.2 encourage you to specify your own --prefix. OpenSSL versions 1.1.1, 1.1.0 and 1.0.2 are affected by this issue. Due to the limited scope of affected deployments this has been assessed as low severity and therefore we are not creating new releases at this time. |
Affected by 11 other vulnerabilities. Affected by 0 other vulnerabilities. Affected by 13 other vulnerabilities. |
|
VCID-q9r2-dz2p-aaap
Aliases: CVE-2019-1563 VC-OPENSSL-20190910-CVE-2019-1563 |
In situations where an attacker receives automated notification of the success or failure of a decryption attempt an attacker, after sending a very large number of messages to be decrypted, can recover a CMS/PKCS7 transported encryption key or decrypt any RSA encrypted message that was encrypted with the public RSA key, using a Bleichenbacher padding oracle attack. Applications are not affected if they use a certificate together with the private RSA key to the CMS_decrypt or PKCS7_decrypt functions to select the correct recipient info to decrypt. Fixed in OpenSSL 1.1.1d (Affected 1.1.1-1.1.1c). Fixed in OpenSSL 1.1.0l (Affected 1.1.0-1.1.0k). Fixed in OpenSSL 1.0.2t (Affected 1.0.2-1.0.2s). |
Affected by 11 other vulnerabilities. Affected by 0 other vulnerabilities. Affected by 13 other vulnerabilities. |
|
VCID-qbz3-r843-aaaf
Aliases: CVE-2016-2183 VC-OPENSSL-20160824-CVE-2016-2183 |
The DES and Triple DES ciphers, as used in the TLS, SSH, and IPSec protocols and other protocols and products, have a birthday bound of approximately four billion blocks, which makes it easier for remote attackers to obtain cleartext data via a birthday attack against a long-duration encrypted session, as demonstrated by an HTTPS session using Triple DES in CBC mode, aka a "Sweet32" attack. |
Affected by 27 other vulnerabilities. |
|
VCID-qkh6-sakf-aaar
Aliases: CVE-2017-3732 VC-OPENSSL-20170126-CVE-2017-3732 |
There is a carry propagating bug in the x86_64 Montgomery squaring procedure in OpenSSL 1.0.2 before 1.0.2k and 1.1.0 before 1.1.0d. No EC algorithms are affected. Analysis suggests that attacks against RSA and DSA as a result of this defect would be very difficult to perform and are not believed likely. Attacks against DH are considered just feasible (although very difficult) because most of the work necessary to deduce information about a private key may be performed offline. The amount of resources required for such an attack would be very significant and likely only accessible to a limited number of attackers. An attacker would additionally need online access to an unpatched system using the target private key in a scenario with persistent DH parameters and a private key that is shared between multiple clients. For example this can occur by default in OpenSSL DHE based SSL/TLS ciphersuites. Note: This issue is very similar to CVE-2015-3193 but must be treated as a separate problem. |
Affected by 23 other vulnerabilities. Affected by 15 other vulnerabilities. |
|
VCID-qtbw-vpbp-aaaj
Aliases: CVE-2021-4160 VC-OPENSSL-20220128-CVE-2021-4160 |
There is a carry propagation bug in the MIPS32 and MIPS64 squaring procedure. Many EC algorithms are affected, including some of the TLS 1.3 default curves. Impact was not analyzed in detail, because the pre-requisites for attack are considered unlikely and include reusing private keys. Analysis suggests that attacks against RSA and DSA as a result of this defect would be very difficult to perform and are not believed likely. Attacks against DH are considered just feasible (although very difficult) because most of the work necessary to deduce information about a private key may be performed offline. The amount of resources required for such an attack would be significant. However, for an attack on TLS to be meaningful, the server would have to share the DH private key among multiple clients, which is no longer an option since CVE-2016-0701. This issue affects OpenSSL versions 1.0.2, 1.1.1 and 3.0.0. It was addressed in the releases of 1.1.1m and 3.0.1 on the 15th of December 2021. For the 1.0.2 release it is addressed in git commit 6fc1aaaf3 that is available to premium support customers only. It will be made available in 1.0.2zc when it is released. The issue only affects OpenSSL on MIPS platforms. |
Affected by 3 other vulnerabilities. Affected by 0 other vulnerabilities. Affected by 4 other vulnerabilities. Affected by 10 other vulnerabilities. |
|
VCID-sgbg-ntsk-aaac
Aliases: CVE-2016-6303 VC-OPENSSL-20160824-CVE-2016-6303 |
Integer overflow in the MDC2_Update function in crypto/mdc2/mdc2dgst.c in OpenSSL before 1.1.0 allows remote attackers to cause a denial of service (out-of-bounds write and application crash) or possibly have unspecified other impact via unknown vectors. |
Affected by 27 other vulnerabilities. |
|
VCID-t9zu-eqq1-aaag
Aliases: CVE-2016-0702 VC-OPENSSL-20160301-CVE-2016-0702 |
A side-channel attack was found which makes use of cache-bank conflicts on the Intel Sandy-Bridge microarchitecture which could lead to the recovery of RSA keys. The ability to exploit this issue is limited as it relies on an attacker who has control of code in a thread running on the same hyper-threaded core as the victim thread which is performing decryptions. |
Affected by 42 other vulnerabilities. |
|
VCID-ue1t-xset-aaah
Aliases: CVE-2016-2180 VC-OPENSSL-20160722-CVE-2016-2180 |
The TS_OBJ_print_bio function in crypto/ts/ts_lib.c in the X.509 Public Key Infrastructure Time-Stamp Protocol (TSP) implementation in OpenSSL through 1.0.2h allows remote attackers to cause a denial of service (out-of-bounds read and application crash) via a crafted time-stamp file that is mishandled by the "openssl ts" command. |
Affected by 27 other vulnerabilities. |
|
VCID-uh6s-bvxe-aaaf
Aliases: CVE-2016-0797 VC-OPENSSL-20160301-CVE-2016-0797 |
In the BN_hex2bn function the number of hex digits is calculated using an int value |i|. Later |bn_expand| is called with a value of |i * 4|. For large values of |i| this can result in |bn_expand| not allocating any memory because |i * 4| is negative. This can leave the internal BIGNUM data field as NULL leading to a subsequent NULL ptr deref. For very large values of |i|, the calculation |i * 4| could be a positive value smaller than |i|. In this case memory is allocated to the internal BIGNUM data field, but it is insufficiently sized leading to heap corruption. A similar issue exists in BN_dec2bn. This could have security consequences if BN_hex2bn/BN_dec2bn is ever called by user applications with very large untrusted hex/dec data. This is anticipated to be a rare occurrence. All OpenSSL internal usage of these functions use data that is not expected to be untrusted, e.g. config file data or application command line arguments. If user developed applications generate config file data based on untrusted data then it is possible that this could also lead to security consequences. This is also anticipated to be rare. |
Affected by 42 other vulnerabilities. |
|
VCID-vc4y-g9fg-aaak
Aliases: CVE-2021-23840 GHSA-qgm6-9472-pwq7 VC-OPENSSL-20210216-CVE-2021-23840 |
Calls to EVP_CipherUpdate, EVP_EncryptUpdate and EVP_DecryptUpdate may overflow the output length argument in some cases where the input length is close to the maximum permissable length for an integer on the platform. In such cases the return value from the function call will be 1 (indicating success), but the output length value will be negative. This could cause applications to behave incorrectly or crash. OpenSSL versions 1.1.1i and below are affected by this issue. Users of these versions should upgrade to OpenSSL 1.1.1j. OpenSSL versions 1.0.2x and below are affected by this issue. However OpenSSL 1.0.2 is out of support and no longer receiving public updates. Premium support customers of OpenSSL 1.0.2 should upgrade to 1.0.2y. Other users should upgrade to 1.1.1j. Fixed in OpenSSL 1.1.1j (Affected 1.1.1-1.1.1i). Fixed in OpenSSL 1.0.2y (Affected 1.0.2-1.0.2x). |
Affected by 5 other vulnerabilities. Affected by 9 other vulnerabilities. |
|
VCID-vm2m-bf4p-aaaf
Aliases: CVE-2019-1559 VC-OPENSSL-20190226-CVE-2019-1559 |
Affected by 13 other vulnerabilities. |
|
|
VCID-vz46-gfhm-aaap
Aliases: CVE-2016-0800 VC-OPENSSL-20160301-CVE-2016-0800 |
A cross-protocol attack was discovered that could lead to decryption of TLS sessions by using a server supporting SSLv2 and EXPORT cipher suites as a Bleichenbacher RSA padding oracle. Note that traffic between clients and non-vulnerable servers can be decrypted provided another server supporting SSLv2 and EXPORT ciphers (even with a different protocol such as SMTP, IMAP or POP) shares the RSA keys of the non-vulnerable server. This vulnerability is known as DROWN (CVE-2016-0800). Recovering one session key requires the attacker to perform approximately 2^50 computation, as well as thousands of connections to the affected server. A more efficient variant of the DROWN attack exists against unpatched OpenSSL servers using versions that predate 1.0.2a, 1.0.1m, 1.0.0r and 0.9.8zf released on 19/Mar/2015 (see CVE-2016-0703 below). Users can avoid this issue by disabling the SSLv2 protocol in all their SSL/TLS servers, if they've not done so already. Disabling all SSLv2 ciphers is also sufficient, provided the patches for CVE-2015-3197 (fixed in OpenSSL 1.0.1r and 1.0.2f) have been deployed. Servers that have not disabled the SSLv2 protocol, and are not patched for CVE-2015-3197 are vulnerable to DROWN even if all SSLv2 ciphers are nominally disabled, because malicious clients can force the use of SSLv2 with EXPORT ciphers. OpenSSL 1.0.2g and 1.0.1s deploy the following mitigation against DROWN: SSLv2 is now by default disabled at build-time. Builds that are not configured with "enable-ssl2" will not support SSLv2. Even if "enable-ssl2" is used, users who want to negotiate SSLv2 via the version-flexible SSLv23_method() will need to explicitly call either of: SSL_CTX_clear_options(ctx, SSL_OP_NO_SSLv2); or SSL_clear_options(ssl, SSL_OP_NO_SSLv2); as appropriate. Even if either of those is used, or the application explicitly uses the version-specific SSLv2_method() or its client or server variants, SSLv2 ciphers vulnerable to exhaustive search key recovery have been removed. Specifically, the SSLv2 40-bit EXPORT ciphers, and SSLv2 56-bit DES are no longer available. In addition, weak ciphers in SSLv3 and up are now disabled in default builds of OpenSSL. Builds that are not configured with "enable-weak-ssl-ciphers" will not provide any "EXPORT" or "LOW" strength ciphers. |
Affected by 42 other vulnerabilities. |
|
VCID-w17h-u8wd-aaaj
Aliases: CVE-2022-2068 VC-OPENSSL-20220621-CVE-2022-2068 |
In addition to the c_rehash shell command injection identified in CVE-2022-1292, further circumstances where the c_rehash script does not properly sanitise shell metacharacters to prevent command injection were found by code review. When the CVE-2022-1292 was fixed it was not discovered that there are other places in the script where the file names of certificates being hashed were possibly passed to a command executed through the shell. This script is distributed by some operating systems in a manner where it is automatically executed. On such operating systems, an attacker could execute arbitrary commands with the privileges of the script. Use of the c_rehash script is considered obsolete and should be replaced by the OpenSSL rehash command line tool. Fixed in OpenSSL 3.0.4 (Affected 3.0.0,3.0.1,3.0.2,3.0.3). Fixed in OpenSSL 1.1.1p (Affected 1.1.1-1.1.1o). Fixed in OpenSSL 1.0.2zf (Affected 1.0.2-1.0.2ze). |
Affected by 0 other vulnerabilities. Affected by 1 other vulnerability. Affected by 5 other vulnerabilities. |
|
VCID-w3xz-a1z2-aaaf
Aliases: CVE-2017-3731 VC-OPENSSL-20170126-CVE-2017-3731 |
If an SSL/TLS server or client is running on a 32-bit host, and a specific cipher is being used, then a truncated packet can cause that server or client to perform an out-of-bounds read, usually resulting in a crash. For OpenSSL 1.1.0, the crash can be triggered when using CHACHA20/POLY1305; users should upgrade to 1.1.0d. For Openssl 1.0.2, the crash can be triggered when using RC4-MD5; users who have not disabled that algorithm should update to 1.0.2k. |
Affected by 23 other vulnerabilities. Affected by 15 other vulnerabilities. |
|
VCID-wdvv-5wyx-aaaa
Aliases: CVE-2016-2176 VC-OPENSSL-20160503-CVE-2016-2176 |
The X509_NAME_oneline function in crypto/x509/x509_obj.c in OpenSSL before 1.0.1t and 1.0.2 before 1.0.2h allows remote attackers to obtain sensitive information from process stack memory or cause a denial of service (buffer over-read) via crafted EBCDIC ASN.1 data. |
Affected by 37 other vulnerabilities. |
|
VCID-xsy7-be4x-aaas
Aliases: CVE-2016-2106 VC-OPENSSL-20160503-CVE-2016-2106 |
Integer overflow in the EVP_EncryptUpdate function in crypto/evp/evp_enc.c in OpenSSL before 1.0.1t and 1.0.2 before 1.0.2h allows remote attackers to cause a denial of service (heap memory corruption) via a large amount of data. |
Affected by 37 other vulnerabilities. |
|
VCID-y2q8-1hgf-aaak
Aliases: CVE-2019-1551 VC-OPENSSL-20191206-CVE-2019-1551 |
There is an overflow bug in the x64_64 Montgomery squaring procedure used in exponentiation with 512-bit moduli. No EC algorithms are affected. Analysis suggests that attacks against 2-prime RSA1024, 3-prime RSA1536, and DSA1024 as a result of this defect would be very difficult to perform and are not believed likely. Attacks against DH512 are considered just feasible. However, for an attack the target would have to re-use the DH512 private key, which is not recommended anyway. Also applications directly using the low level API BN_mod_exp may be affected if they use BN_FLG_CONSTTIME. Fixed in OpenSSL 1.1.1e (Affected 1.1.1-1.1.1d). Fixed in OpenSSL 1.0.2u (Affected 1.0.2-1.0.2t). |
Affected by 10 other vulnerabilities. Affected by 12 other vulnerabilities. |
|
VCID-y471-3h22-aaah
Aliases: CVE-2016-7055 VC-OPENSSL-20161110-CVE-2016-7055 |
There is a carry propagating bug in the Broadwell-specific Montgomery multiplication procedure in OpenSSL 1.0.2 and 1.1.0 before 1.1.0c that handles input lengths divisible by, but longer than 256 bits. Analysis suggests that attacks against RSA, DSA and DH private keys are impossible. This is because the subroutine in question is not used in operations with the private key itself and an input of the attacker's direct choice. Otherwise the bug can manifest itself as transient authentication and key negotiation failures or reproducible erroneous outcome of public-key operations with specially crafted input. Among EC algorithms only Brainpool P-512 curves are affected and one presumably can attack ECDH key negotiation. Impact was not analyzed in detail, because pre-requisites for attack are considered unlikely. Namely multiple clients have to choose the curve in question and the server has to share the private key among them, neither of which is default behaviour. Even then only clients that chose the curve will be affected. |
Affected by 23 other vulnerabilities. Affected by 18 other vulnerabilities. |
|
VCID-yrx6-rcrr-aaap
Aliases: CVE-2022-1292 VC-OPENSSL-20220503-CVE-2022-1292 |
The c_rehash script does not properly sanitise shell metacharacters to prevent command injection. This script is distributed by some operating systems in a manner where it is automatically executed. On such operating systems, an attacker could execute arbitrary commands with the privileges of the script. Use of the c_rehash script is considered obsolete and should be replaced by the OpenSSL rehash command line tool. Fixed in OpenSSL 3.0.3 (Affected 3.0.0,3.0.1,3.0.2). Fixed in OpenSSL 1.1.1o (Affected 1.1.1-1.1.1n). Fixed in OpenSSL 1.0.2ze (Affected 1.0.2-1.0.2zd). |
Affected by 1 other vulnerability. Affected by 2 other vulnerabilities. Affected by 5 other vulnerabilities. |
|
VCID-ys3w-wua9-aaas
Aliases: CVE-2017-3736 VC-OPENSSL-20171102-CVE-2017-3736 |
There is a carry propagating bug in the x86_64 Montgomery squaring procedure in OpenSSL before 1.0.2m and 1.1.0 before 1.1.0g. No EC algorithms are affected. Analysis suggests that attacks against RSA and DSA as a result of this defect would be very difficult to perform and are not believed likely. Attacks against DH are considered just feasible (although very difficult) because most of the work necessary to deduce information about a private key may be performed offline. The amount of resources required for such an attack would be very significant and likely only accessible to a limited number of attackers. An attacker would additionally need online access to an unpatched system using the target private key in a scenario with persistent DH parameters and a private key that is shared between multiple clients. This only affects processors that support the BMI1, BMI2 and ADX extensions like Intel Broadwell (5th generation) and later or AMD Ryzen. |
Affected by 21 other vulnerabilities. Affected by 12 other vulnerabilities. |
|
VCID-z6bg-hyhu-aaas
Aliases: CVE-2016-2178 VC-OPENSSL-20160607-CVE-2016-2178 |
The dsa_sign_setup function in crypto/dsa/dsa_ossl.c in OpenSSL through 1.0.2h does not properly ensure the use of constant-time operations, which makes it easier for local users to discover a DSA private key via a timing side-channel attack. |
Affected by 27 other vulnerabilities. |
|
VCID-zesf-f628-aaad
Aliases: CVE-2017-3737 VC-OPENSSL-20171207-CVE-2017-3737 |
OpenSSL 1.0.2 (starting from version 1.0.2b) introduced an "error state" mechanism. The intent was that if a fatal error occurred during a handshake then OpenSSL would move into the error state and would immediately fail if you attempted to continue the handshake. This works as designed for the explicit handshake functions (SSL_do_handshake(), SSL_accept() and SSL_connect()), however due to a bug it does not work correctly if SSL_read() or SSL_write() is called directly. In that scenario, if the handshake fails then a fatal error will be returned in the initial function call. If SSL_read()/SSL_write() is subsequently called by the application for the same SSL object then it will succeed and the data is passed without being decrypted/encrypted directly from the SSL/TLS record layer. In order to exploit this issue an application bug would have to be present that resulted in a call to SSL_read()/SSL_write() being issued after having already received a fatal error. OpenSSL version 1.0.2b-1.0.2m are affected. Fixed in OpenSSL 1.0.2n. OpenSSL 1.1.0 is not affected. |
Affected by 19 other vulnerabilities. |
| Vulnerability | Summary | Aliases |
|---|---|---|
| VCID-68v4-qbae-aaak | A malicious client can negotiate SSLv2 ciphers that have been disabled on the server and complete SSLv2 handshakes even if all SSLv2 ciphers have been disabled, provided that the SSLv2 protocol was not also disabled via SSL_OP_NO_SSLv2. |
CVE-2015-3197
VC-OPENSSL-20160128-CVE-2015-3197 |
| VCID-w8mr-jycm-aaag | Historically OpenSSL usually only ever generated DH parameters based on "safe" primes. More recently (in version 1.0.2) support was provided for generating X9.42 style parameter files such as those required for RFC 5114 support. The primes used in such files may not be "safe". Where an application is using DH configured with parameters based on primes that are not "safe" then an attacker could use this fact to find a peer's private DH exponent. This attack requires that the attacker complete multiple handshakes in which the peer uses the same private DH exponent. For example this could be used to discover a TLS server's private DH exponent if it's reusing the private DH exponent or it's using a static DH ciphersuite. OpenSSL provides the option SSL_OP_SINGLE_DH_USE for ephemeral DH (DHE) in TLS. It is not on by default. If the option is not set then the server reuses the same private DH exponent for the life of the server process and would be vulnerable to this attack. It is believed that many popular applications do set this option and would therefore not be at risk. OpenSSL before 1.0.2f will reuse the key if: - SSL_CTX_set_tmp_dh()/SSL_set_tmp_dh() is used and SSL_OP_SINGLE_DH_USE is not set. - SSL_CTX_set_tmp_dh_callback()/SSL_set_tmp_dh_callback() is used, and both the parameters and the key are set and SSL_OP_SINGLE_DH_USE is not used. This is an undocumted feature and parameter files don't contain the key. - Static DH ciphersuites are used. The key is part of the certificate and so it will always reuse it. This is only supported in 1.0.2. It will not reuse the key for DHE ciphers suites if: - SSL_OP_SINGLE_DH_USE is set - SSL_CTX_set_tmp_dh_callback()/SSL_set_tmp_dh_callback() is used and the callback does not provide the key, only the parameters. The callback is almost always used like this. Non-safe primes are generated by OpenSSL when using: - genpkey with the dh_rfc5114 option. This will write an X9.42 style file including the prime-order subgroup size "q". This is supported since the 1.0.2 version. Older versions can't read files generated in this way. - dhparam with the -dsaparam option. This has always been documented as requiring the single use. The fix for this issue adds an additional check where a "q" parameter is available (as is the case in X9.42 based parameters). This detects the only known attack, and is the only possible defense for static DH ciphersuites. This could have some performance impact. Additionally the SSL_OP_SINGLE_DH_USE option has been switched on by default and cannot be disabled. This could have some performance impact. |
CVE-2016-0701
VC-OPENSSL-20160128-CVE-2016-0701 |
| Date | Actor | Action | Vulnerability | Source | VulnerableCode Version |
|---|---|---|---|---|---|
| 2024-01-03T20:01:36.725454+00:00 | OpenSSL Importer | Fixing | VCID-68v4-qbae-aaak | https://www.openssl.org/news/secadv/20160128.txt | 34.0.0rc1 |
| 2024-01-03T20:01:36.577295+00:00 | OpenSSL Importer | Fixing | VCID-w8mr-jycm-aaag | https://www.openssl.org/news/secadv/20160128.txt | 34.0.0rc1 |
| 2024-01-03T20:01:35.773657+00:00 | OpenSSL Importer | Affected by | VCID-t9zu-eqq1-aaag | https://www.openssl.org/news/secadv/20160301.txt | 34.0.0rc1 |
| 2024-01-03T20:01:35.587161+00:00 | OpenSSL Importer | Affected by | VCID-9wtw-93e9-aaam | https://www.openssl.org/news/secadv/20160301.txt | 34.0.0rc1 |
| 2024-01-03T20:01:35.423436+00:00 | OpenSSL Importer | Affected by | VCID-uh6s-bvxe-aaaf | https://www.openssl.org/news/secadv/20160301.txt | 34.0.0rc1 |
| 2024-01-03T20:01:35.261170+00:00 | OpenSSL Importer | Affected by | VCID-m4nz-uw2e-aaaq | https://www.openssl.org/news/secadv/20160301.txt | 34.0.0rc1 |
| 2024-01-03T20:01:35.085392+00:00 | OpenSSL Importer | Affected by | VCID-ejg3-awxf-aaan | https://www.openssl.org/news/secadv/20160301.txt | 34.0.0rc1 |
| 2024-01-03T20:01:34.918670+00:00 | OpenSSL Importer | Affected by | VCID-vz46-gfhm-aaap | https://www.openssl.org/news/secadv/20160301.txt | 34.0.0rc1 |
| 2024-01-03T20:01:34.737879+00:00 | OpenSSL Importer | Affected by | VCID-wdvv-5wyx-aaaa | https://www.openssl.org/news/secadv/20160503.txt | 34.0.0rc1 |
| 2024-01-03T20:01:34.566774+00:00 | OpenSSL Importer | Affected by | VCID-egbc-ecck-aaag | https://www.openssl.org/news/secadv/20160503.txt | 34.0.0rc1 |
| 2024-01-03T20:01:34.394651+00:00 | OpenSSL Importer | Affected by | VCID-xsy7-be4x-aaas | https://www.openssl.org/news/secadv/20160503.txt | 34.0.0rc1 |
| 2024-01-03T20:01:34.227396+00:00 | OpenSSL Importer | Affected by | VCID-42tc-p92q-aaap | https://www.openssl.org/news/secadv/20160503.txt | 34.0.0rc1 |
| 2024-01-03T20:01:34.052652+00:00 | OpenSSL Importer | Affected by | VCID-cg17-ah7e-aaag | https://www.openssl.org/news/secadv/20160503.txt | 34.0.0rc1 |
| 2024-01-03T20:01:33.697659+00:00 | OpenSSL Importer | Affected by | VCID-eg7n-8h8z-aaaa | https://www.openssl.org/news/secadv/20160922.txt | 34.0.0rc1 |
| 2024-01-03T20:01:33.503789+00:00 | OpenSSL Importer | Affected by | VCID-a12s-yyr4-aaad | https://www.openssl.org/news/secadv/20160922.txt | 34.0.0rc1 |
| 2024-01-03T20:01:33.311412+00:00 | OpenSSL Importer | Affected by | VCID-9fjn-9378-aaae | https://www.openssl.org/news/secadv/20160922.txt | 34.0.0rc1 |
| 2024-01-03T20:01:33.120378+00:00 | OpenSSL Importer | Affected by | VCID-z6bg-hyhu-aaas | https://www.openssl.org/news/secadv/20160922.txt | 34.0.0rc1 |
| 2024-01-03T20:01:32.938283+00:00 | OpenSSL Importer | Affected by | VCID-kryh-pfgh-aaag | https://www.openssl.org/news/secadv/20160922.txt | 34.0.0rc1 |
| 2024-01-03T20:01:32.748704+00:00 | OpenSSL Importer | Affected by | VCID-ue1t-xset-aaah | https://www.openssl.org/news/secadv/20160922.txt | 34.0.0rc1 |
| 2024-01-03T20:01:32.564150+00:00 | OpenSSL Importer | Affected by | VCID-agz8-77e4-aaaq | https://www.openssl.org/news/secadv/20160922.txt | 34.0.0rc1 |
| 2024-01-03T20:01:32.384381+00:00 | OpenSSL Importer | Affected by | VCID-581z-anfk-aaaq | https://www.openssl.org/news/secadv/20160922.txt | 34.0.0rc1 |
| 2024-01-03T20:01:32.195452+00:00 | OpenSSL Importer | Affected by | VCID-sgbg-ntsk-aaac | https://www.openssl.org/news/secadv/20160922.txt | 34.0.0rc1 |
| 2024-01-03T20:01:31.938722+00:00 | OpenSSL Importer | Affected by | VCID-bms1-jrax-aaap | https://www.openssl.org/news/secadv/20160922.txt | 34.0.0rc1 |
| 2024-01-03T20:01:31.668948+00:00 | OpenSSL Importer | Affected by | VCID-y471-3h22-aaah | https://www.openssl.org/news/secadv/20161110.txt | 34.0.0rc1 |
| 2024-01-03T20:01:31.487075+00:00 | OpenSSL Importer | Affected by | VCID-qbz3-r843-aaaf | https://www.openssl.org/blog/blog/2016/08/24/sweet32/ | 34.0.0rc1 |
| 2024-01-03T20:01:31.412659+00:00 | OpenSSL Importer | Affected by | VCID-qkh6-sakf-aaar | https://www.openssl.org/news/secadv/20170126.txt | 34.0.0rc1 |
| 2024-01-03T20:01:31.253560+00:00 | OpenSSL Importer | Affected by | VCID-w3xz-a1z2-aaaf | https://www.openssl.org/news/secadv/20170126.txt | 34.0.0rc1 |
| 2024-01-03T20:01:31.076799+00:00 | OpenSSL Importer | Affected by | VCID-jhg8-wbm2-aaas | https://www.openssl.org/news/secadv/20170828.txt | 34.0.0rc1 |
| 2024-01-03T20:01:30.927803+00:00 | OpenSSL Importer | Affected by | VCID-ys3w-wua9-aaas | https://www.openssl.org/news/secadv/20171102.txt | 34.0.0rc1 |
| 2024-01-03T20:01:30.778310+00:00 | OpenSSL Importer | Affected by | VCID-4hq6-j84v-aaan | https://www.openssl.org/news/secadv/20171207.txt | 34.0.0rc1 |
| 2024-01-03T20:01:30.625396+00:00 | OpenSSL Importer | Affected by | VCID-zesf-f628-aaad | https://www.openssl.org/news/secadv/20171207.txt | 34.0.0rc1 |
| 2024-01-03T20:01:30.471073+00:00 | OpenSSL Importer | Affected by | VCID-fmvb-j6br-aaap | https://www.openssl.org/news/secadv/20180327.txt | 34.0.0rc1 |
| 2024-01-03T20:01:30.317281+00:00 | OpenSSL Importer | Affected by | VCID-j8pb-xdpc-aaap | https://www.openssl.org/news/secadv/20180416.txt | 34.0.0rc1 |
| 2024-01-03T20:01:30.155426+00:00 | OpenSSL Importer | Affected by | VCID-9cyz-en38-aaad | https://www.openssl.org/news/secadv/20180612.txt | 34.0.0rc1 |
| 2024-01-03T20:01:29.885708+00:00 | OpenSSL Importer | Affected by | VCID-psvb-thr2-aaap | https://www.openssl.org/news/secadv/20181030.txt | 34.0.0rc1 |
| 2024-01-03T20:01:29.672274+00:00 | OpenSSL Importer | Affected by | VCID-ceua-4xhz-aaag | https://www.openssl.org/news/secadv/20181112.txt | 34.0.0rc1 |
| 2024-01-03T20:01:29.494059+00:00 | OpenSSL Importer | Affected by | VCID-vm2m-bf4p-aaaf | https://www.openssl.org/news/secadv/20190226.txt | 34.0.0rc1 |
| 2024-01-03T20:01:29.266556+00:00 | OpenSSL Importer | Affected by | VCID-pzng-q94v-aaah | https://www.openssl.org/news/secadv/20190730.txt | 34.0.0rc1 |
| 2024-01-03T20:01:29.014778+00:00 | OpenSSL Importer | Affected by | VCID-q9r2-dz2p-aaap | https://www.openssl.org/news/secadv/20190910.txt | 34.0.0rc1 |
| 2024-01-03T20:01:28.721948+00:00 | OpenSSL Importer | Affected by | VCID-1gxv-1j1x-aaag | https://www.openssl.org/news/secadv/20190910.txt | 34.0.0rc1 |
| 2024-01-03T20:01:28.473536+00:00 | OpenSSL Importer | Affected by | VCID-y2q8-1hgf-aaak | https://www.openssl.org/news/secadv/20191206.txt | 34.0.0rc1 |
| 2024-01-03T20:01:28.251990+00:00 | OpenSSL Importer | Affected by | VCID-msmt-6x6r-aaaj | https://www.openssl.org/news/secadv/20200909.txt | 34.0.0rc1 |
| 2024-01-03T20:01:28.111882+00:00 | OpenSSL Importer | Affected by | VCID-nx9u-49dk-aaag | https://www.openssl.org/news/secadv/20201208.txt | 34.0.0rc1 |
| 2024-01-03T20:01:27.889959+00:00 | OpenSSL Importer | Affected by | VCID-vc4y-g9fg-aaak | https://www.openssl.org/news/secadv/20210216.txt | 34.0.0rc1 |
| 2024-01-03T20:01:27.614177+00:00 | OpenSSL Importer | Affected by | VCID-9ruy-372r-aaas | https://www.openssl.org/news/secadv/20210216.txt | 34.0.0rc1 |
| 2024-01-03T20:01:27.274804+00:00 | OpenSSL Importer | Affected by | VCID-ghgs-7167-aaag | https://www.openssl.org/news/secadv/20210824.txt | 34.0.0rc1 |
| 2024-01-03T20:01:26.934658+00:00 | OpenSSL Importer | Affected by | VCID-qtbw-vpbp-aaaj | https://www.openssl.org/news/secadv/20220128.txt | 34.0.0rc1 |
| 2024-01-03T20:01:26.658692+00:00 | OpenSSL Importer | Affected by | VCID-6pjh-cgdt-aaaj | https://www.openssl.org/news/secadv/20220315.txt | 34.0.0rc1 |
| 2024-01-03T20:01:26.265714+00:00 | OpenSSL Importer | Affected by | VCID-yrx6-rcrr-aaap | https://www.openssl.org/news/secadv/20220503.txt | 34.0.0rc1 |
| 2024-01-03T20:01:25.957342+00:00 | OpenSSL Importer | Affected by | VCID-w17h-u8wd-aaaj | https://www.openssl.org/news/secadv/20220621.txt | 34.0.0rc1 |