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2018-01-04
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CVE-2017-5715
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Systems with microprocessors utilizing speculative execution and indirect branch prediction may allow unauthorized disclosure of information to an attacker with local user access via a side-channel analysis.
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Cortex\-A, Ubuntu_linux, Debian_linux, Atom_c, Atom_e, Atom_x3, Atom_x5\-E3930, Atom_x5\-E3940, Atom_x7\-E3950, Atom_z, Celeron_j, Celeron_n, Core_i3, Core_i5, Core_i7, Core_m, Core_m3, Core_m5, Core_m7, Pentium_j, Pentium_n, Xeon, Xeon_bronze_3104, Xeon_bronze_3106, Xeon_e3, Xeon_e3_1105c_v2, Xeon_e3_1125c, Xeon_e3_1125c_v2, Xeon_e3_1220, Xeon_e3_12201, Xeon_e3_12201_v2, Xeon_e3_1220_v2, Xeon_e3_1220_v3, Xeon_e3_1220_v5, Xeon_e3_1220_v6, Xeon_e3_1220l_v3, Xeon_e3_1225, Xeon_e3_1225_v2, Xeon_e3_1225_v3, Xeon_e3_1225_v5, Xeon_e3_1225_v6, Xeon_e3_1226_v3, Xeon_e3_1230, Xeon_e3_1230_v2, Xeon_e3_1230_v3, Xeon_e3_1230_v5, Xeon_e3_1230_v6, Xeon_e3_1230l_v3, Xeon_e3_1231_v3, Xeon_e3_1235, Xeon_e3_1235l_v5, Xeon_e3_1240, Xeon_e3_1240_v2, Xeon_e3_1240_v3, Xeon_e3_1240_v5, Xeon_e3_1240_v6, Xeon_e3_1240l_v3, Xeon_e3_1240l_v5, Xeon_e3_1241_v3, Xeon_e3_1245, Xeon_e3_1245_v2, Xeon_e3_1245_v3, Xeon_e3_1245_v5, Xeon_e3_1245_v6, Xeon_e3_1246_v3, Xeon_e3_1258l_v4, Xeon_e3_1260l, Xeon_e3_1260l_v5, Xeon_e3_1265l_v2, Xeon_e3_1265l_v3, Xeon_e3_1265l_v4, Xeon_e3_1268l_v3, Xeon_e3_1268l_v5, Xeon_e3_1270, Xeon_e3_1270_v2, Xeon_e3_1270_v3, Xeon_e3_1270_v5, Xeon_e3_1270_v6, Xeon_e3_1271_v3, Xeon_e3_1275, Xeon_e3_1275_v2, Xeon_e3_1275_v3, Xeon_e3_1275_v5, Xeon_e3_1275_v6, Xeon_e3_1275l_v3, Xeon_e3_1276_v3, Xeon_e3_1278l_v4, Xeon_e3_1280, Xeon_e3_1280_v2, Xeon_e3_1280_v3, Xeon_e3_1280_v5, Xeon_e3_1280_v6, Xeon_e3_1281_v3, Xeon_e3_1285_v3, Xeon_e3_1285_v4, Xeon_e3_1285_v6, Xeon_e3_1285l_v3, Xeon_e3_1285l_v4, Xeon_e3_1286_v3, Xeon_e3_1286l_v3, Xeon_e3_1290, Xeon_e3_1290_v2, Xeon_e3_1501l_v6, Xeon_e3_1501m_v6, Xeon_e3_1505l_v5, Xeon_e3_1505l_v6, Xeon_e3_1505m_v5, Xeon_e5, Xeon_e5_1428l, Xeon_e5_1428l_v2, Xeon_e5_1428l_v3, Xeon_e5_1620, Xeon_e5_1620_v2, Xeon_e5_1620_v3, Xeon_e5_1620_v4, Xeon_e5_1630_v3, Xeon_e5_1630_v4, Xeon_e5_1650, Xeon_e5_1650_v2, Xeon_e5_1650_v3, Xeon_e5_1650_v4, Xeon_e5_1660, Xeon_e5_1660_v2, Xeon_e5_1660_v3, Xeon_e5_1660_v4, Xeon_e5_1680_v3, Xeon_e5_1680_v4, Xeon_e5_2403, Xeon_e5_2403_v2, Xeon_e5_2407, Xeon_e5_2407_v2, Xeon_e5_2408l_v3, Xeon_e5_2418l, Xeon_e5_2418l_v2, Xeon_e5_2418l_v3, Xeon_e5_2420, Xeon_e5_2420_v2, Xeon_e5_2428l, Xeon_e5_2428l_v2, Xeon_e5_2428l_v3, Xeon_e5_2430, Xeon_e5_2430_v2, Xeon_e5_2430l, Xeon_e5_2430l_v2, Xeon_e5_2438l_v3, Xeon_e5_2440, Xeon_e5_2440_v2, Xeon_e5_2448l, Xeon_e5_2448l_v2, Xeon_e5_2450, Xeon_e5_2450_v2, Xeon_e5_2450l, Xeon_e5_2450l_v2, Xeon_e5_2470, Xeon_e5_2470_v2, Xeon_e5_2603, Xeon_e5_2603_v2, Xeon_e5_2603_v3, Xeon_e5_2603_v4, Xeon_e5_2608l_v3, Xeon_e5_2608l_v4, Xeon_e5_2609, Xeon_e5_2609_v2, Xeon_e5_2609_v3, Xeon_e5_2609_v4, Xeon_e5_2618l_v2, Xeon_e5_2618l_v3, Xeon_e5_2618l_v4, Xeon_e5_2620, Xeon_e5_2620_v2, Xeon_e5_2620_v3, Xeon_e5_2620_v4, Xeon_e5_2623_v3, Xeon_e5_2623_v4, Xeon_e5_2628l_v2, Xeon_e5_2628l_v3, Xeon_e5_2628l_v4, Xeon_e5_2630, Xeon_e5_2630_v2, Xeon_e5_2630_v3, Xeon_e5_2630_v4, Xeon_e5_2630l, Xeon_e5_2630l_v2, Xeon_e5_2630l_v3, Xeon_e5_2630l_v4, Xeon_e5_2637, Xeon_e5_2637_v2, Xeon_e5_2637_v3, Xeon_e5_2637_v4, Xeon_e5_2640, Xeon_e5_2640_v2, Xeon_e5_2640_v3, Xeon_e5_2640_v4, Xeon_e5_2643, Xeon_e5_2643_v2, Xeon_e5_2643_v3, Xeon_e5_2643_v4, Xeon_e5_2648l, Xeon_e5_2648l_v2, Xeon_e5_2648l_v3, Xeon_e5_2648l_v4, Xeon_e5_2650, Xeon_e5_2650_v2, Xeon_e5_2650_v3, Xeon_e5_2650_v4, Xeon_e5_2650l, Xeon_e5_2650l_v2, Xeon_e5_2650l_v3, Xeon_e7, Xeon_e\-1105c, Xeon_gold, Xeon_phi, Xeon_platinum, Xeon_silver, Hci_compute_node, Hci_management_node, Solidfire, Communications_diameter_signaling_router, Vm_virtualbox, Simatic_winac_rtx_\(F\)_firmware
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5.6
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|
|
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2022-03-25
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CVE-2018-25032
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zlib before 1.2.12 allows memory corruption when deflating (i.e., when compressing) if the input has many distant matches.
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Mac_os_x, Macos, Zulu, Debian_linux, Fedora, Gotoassist, Mariadb, Active_iq_unified_manager, E\-Series_santricity_os_controller, H300s_firmware, H410c_firmware, H410s_firmware, H500s_firmware, H700s_firmware, Hci_compute_node, Management_services_for_element_software, Oncommand_workflow_automation, Ontap_select_deploy_administration_utility, Nokogiri, Python, Scalance_sc622\-2c_firmware, Scalance_sc626\-2c_firmware, Scalance_sc632\-2c_firmware, Scalance_sc636\-2c_firmware, Scalance_sc642\-2c_firmware, Scalance_sc646\-2c_firmware, Zlib
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7.5
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|
|
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2022-07-27
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CVE-2022-36946
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nfqnl_mangle in net/netfilter/nfnetlink_queue.c in the Linux kernel through 5.18.14 allows remote attackers to cause a denial of service (panic) because, in the case of an nf_queue verdict with a one-byte nfta_payload attribute, an skb_pull can encounter a negative skb->len.
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Debian_linux, Linux_kernel, Active_iq_unified_manager, Hci_compute_node, Solidfire_\&_hci_management_node, Solidfire_\&_hci_storage_node, Solidfire_enterprise_sds
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7.5
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|
|
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2022-07-27
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CVE-2022-36946
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nfqnl_mangle in net/netfilter/nfnetlink_queue.c in the Linux kernel through 5.18.14 allows remote attackers to cause a denial of service (panic) because, in the case of an nf_queue verdict with a one-byte nfta_payload attribute, an skb_pull can encounter a negative skb->len.
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Debian_linux, Linux_kernel, Active_iq_unified_manager, Hci_compute_node, Solidfire_\&_hci_management_node, Solidfire_\&_hci_storage_node, Solidfire_enterprise_sds
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7.5
|
|
|
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2022-07-27
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CVE-2022-36946
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nfqnl_mangle in net/netfilter/nfnetlink_queue.c in the Linux kernel through 5.18.14 allows remote attackers to cause a denial of service (panic) because, in the case of an nf_queue verdict with a one-byte nfta_payload attribute, an skb_pull can encounter a negative skb->len.
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Debian_linux, Linux_kernel, Active_iq_unified_manager, Hci_compute_node, Solidfire_\&_hci_management_node, Solidfire_\&_hci_storage_node, Solidfire_enterprise_sds
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7.5
|
|
|
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2022-08-05
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CVE-2022-37434
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zlib through 1.2.12 has a heap-based buffer over-read or buffer overflow in inflate in inflate.c via a large gzip header extra field. NOTE: only applications that call inflateGetHeader are affected. Some common applications bundle the affected zlib source code but may be unable to call inflateGetHeader (e.g., see the nodejs/node reference).
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Ipados, Iphone_os, Macos, Watchos, Debian_linux, Fedora, Active_iq_unified_manager, H300s_firmware, H500s_firmware, H700s_firmware, Hci, Hci_compute_node, Management_services_for_element_software, Oncommand_workflow_automation, Ontap_select_deploy_administration_utility, Storagegrid, Stormshield_network_security, Zlib
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9.8
|
|
|
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2019-07-17
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CVE-2019-13272
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In the Linux kernel before 5.1.17, ptrace_link in kernel/ptrace.c mishandles the recording of the credentials of a process that wants to create a ptrace relationship, which allows local users to obtain root access by leveraging certain scenarios with a parent-child process relationship, where a parent drops privileges and calls execve (potentially allowing control by an attacker). One contributing factor is an object lifetime issue (which can also cause a panic). Another contributing factor...
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Ubuntu_linux, Debian_linux, Fedora, Linux_kernel, Active_iq_unified_manager, Aff_a700s_firmware, E\-Series_performance_analyzer, E\-Series_santricity_os_controller, H410c_firmware, H610s_firmware, Hci_compute_node, Hci_management_node, Service_processor, Solidfire, Steelstore_cloud_integrated_storage, Enterprise_linux, Enterprise_linux_for_arm_64, Enterprise_linux_for_ibm_z_systems, Enterprise_linux_for_real_time, Enterprise_linux_for_real_time_for_nfv, Enterprise_linux_for_real_time_for_nfv_tus, Enterprise_linux_for_real_time_tus
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7.8
|
|
|
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2020-06-29
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CVE-2020-14145
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The client side in OpenSSH 5.7 through 8.4 has an Observable Discrepancy leading to an information leak in the algorithm negotiation. This allows man-in-the-middle attackers to target initial connection attempts (where no host key for the server has been cached by the client). NOTE: some reports state that 8.5 and 8.6 are also affected.
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Active_iq_unified_manager, Aff_a700s_firmware, Hci_compute_node, Hci_management_node, Hci_storage_node, Ontap_select_deploy_administration_utility, Solidfire, Steelstore_cloud_integrated_storage, Openssh
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5.9
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|
|
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2020-07-24
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CVE-2020-15778
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scp in OpenSSH through 8.3p1 allows command injection in the scp.c toremote function, as demonstrated by backtick characters in the destination argument. NOTE: the vendor reportedly has stated that they intentionally omit validation of "anomalous argument transfers" because that could "stand a great chance of breaking existing workflows."
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Fabric_operating_system, A700s_firmware, Active_iq_unified_manager, Hci_compute_node, Hci_management_node, Hci_storage_node, Solidfire, Steelstore_cloud_integrated_storage, Openssh
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7.8
|
|
|
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2020-09-10
|
CVE-2020-25221
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get_gate_page in mm/gup.c in the Linux kernel 5.7.x and 5.8.x before 5.8.7 allows privilege escalation because of incorrect reference counting (caused by gate page mishandling) of the struct page that backs the vsyscall page. The result is a refcount underflow. This can be triggered by any 64-bit process that can use ptrace() or process_vm_readv(), aka CID-9fa2dd946743.
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Linux_kernel, Cloud_backup, Hci_compute_node, Solidfire\,_enterprise_sds_\&_hci_storage_node, Solidfire_\&_hci_management_node, Solidfire_baseboard_management_controller
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7.8
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|
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