2014-09-30
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CVE-2014-6051
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Integer overflow in the MallocFrameBuffer function in vncviewer.c in LibVNCServer 0.9.9 and earlier allows remote VNC servers to cause a denial of service (crash) and possibly execute arbitrary code via an advertisement for a large screen size, which triggers a heap-based buffer overflow.
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Debian_linux, Fedora, Libvncserver, Solaris, Enterprise_linux_server_aus, Enterprise_linux_server_eus
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N/A
|
|
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2018-02-19
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CVE-2018-7225
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An issue was discovered in LibVNCServer through 0.9.11. rfbProcessClientNormalMessage() in rfbserver.c does not sanitize msg.cct.length, leading to access to uninitialized and potentially sensitive data or possibly unspecified other impact (e.g., an integer overflow) via specially crafted VNC packets.
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Ubuntu_linux, Debian_linux, Libvncserver, Enterprise_linux_desktop, Enterprise_linux_server, Enterprise_linux_server_aus, Enterprise_linux_server_eus, Enterprise_linux_server_tus, Enterprise_linux_workstation
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9.8
|
|
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2018-12-19
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CVE-2018-15127
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LibVNC before commit 502821828ed00b4a2c4bef90683d0fd88ce495de contains heap out-of-bound write vulnerability in server code of file transfer extension that can result remote code execution
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Ubuntu_linux, Debian_linux, Libvncserver, Enterprise_linux_desktop, Enterprise_linux_server, Enterprise_linux_server_aus, Enterprise_linux_server_eus, Enterprise_linux_server_tus, Enterprise_linux_workstation
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9.8
|
|
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2018-10-15
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CVE-2018-18073
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Artifex Ghostscript allows attackers to bypass a sandbox protection mechanism by leveraging exposure of system operators in the saved execution stack in an error object.
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Ghostscript, Ubuntu_linux, Debian_linux, Enterprise_linux_desktop, Enterprise_linux_server, Enterprise_linux_server_aus, Enterprise_linux_server_eus, Enterprise_linux_server_tus, Enterprise_linux_workstation
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6.3
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|
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2018-07-10
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CVE-2018-3693
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Systems with microprocessors utilizing speculative execution and branch prediction may allow unauthorized disclosure of information to an attacker with local user access via a speculative buffer overflow and side-channel analysis.
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Cortex\-A, Cortex\-R, Atom_c, Atom_e, Atom_x3, 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, Solidfire_element_os_management_node, Communications_eagle_application_processor, Enterprise_linux, Enterprise_linux_desktop, Enterprise_linux_server, Enterprise_linux_server_aus, Enterprise_linux_server_eus, Enterprise_linux_server_tus, Enterprise_linux_workstation, Struxureware_data_center_expert
|
5.6
|
|
|
2017-11-13
|
CVE-2016-8610
|
A denial of service flaw was found in OpenSSL 0.9.8, 1.0.1, 1.0.2 through 1.0.2h, and 1.1.0 in the way the TLS/SSL protocol defined processing of ALERT packets during a connection handshake. A remote attacker could use this flaw to make a TLS/SSL server consume an excessive amount of CPU and fail to accept connections from other clients.
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Debian_linux, Clustered_data_ontap, Clustered_data_ontap_antivirus_connector, Cn1610_firmware, Data_ontap, Data_ontap_edge, E\-Series_santricity_os_controller, Host_agent, Oncommand_balance, Oncommand_unified_manager, Oncommand_workflow_automation, Ontap_select_deploy, Service_processor, Smi\-S_provider, Snapcenter_server, Snapdrive, Storagegrid, Storagegrid_webscale, Openssl, Enterprise_linux_desktop, Enterprise_linux_server, Enterprise_linux_server_aus, Enterprise_linux_server_eus, Enterprise_linux_server_tus, Enterprise_linux_workstation, Jboss_enterprise_application_platform
|
7.5
|
|
|
2019-01-16
|
CVE-2017-3136
|
A query with a specific set of characteristics could cause a server using DNS64 to encounter an assertion failure and terminate. An attacker could deliberately construct a query, enabling denial-of-service against a server if it was configured to use the DNS64 feature and other preconditions were met. Affects BIND 9.8.0 -> 9.8.8-P1, 9.9.0 -> 9.9.9-P6, 9.9.10b1->9.9.10rc1, 9.10.0 -> 9.10.4-P6, 9.10.5b1->9.10.5rc1, 9.11.0 -> 9.11.0-P3, 9.11.1b1->9.11.1rc1, 9.9.3-S1 -> 9.9.9-S8.
|
Debian_linux, Bind, Data_ontap_edge, Element_software, Oncommand_balance, Enterprise_linux_desktop, Enterprise_linux_server, Enterprise_linux_server_aus, Enterprise_linux_server_eus, Enterprise_linux_server_tus, Enterprise_linux_workstation
|
5.9
|
|
|
2019-03-21
|
CVE-2019-7221
|
The KVM implementation in the Linux kernel through 4.20.5 has a Use-after-Free.
|
Ubuntu_linux, Debian_linux, Fedora, Linux_kernel, Active_iq_performance_analytics_services, Element_software_management_node, Leap, Enterprise_linux, Enterprise_linux_desktop, Enterprise_linux_server, Enterprise_linux_server_aus, Enterprise_linux_server_eus, Enterprise_linux_server_tus, Enterprise_linux_workstation, Openshift_container_platform
|
7.8
|
|
|
2019-02-15
|
CVE-2019-6974
|
In the Linux kernel before 4.20.8, kvm_ioctl_create_device in virt/kvm/kvm_main.c mishandles reference counting because of a race condition, leading to a use-after-free.
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Ubuntu_linux, Debian_linux, Big\-Ip_access_policy_manager, Big\-Ip_advanced_firewall_manager, Big\-Ip_analytics, Big\-Ip_application_acceleration_manager, Big\-Ip_application_security_manager, Big\-Ip_edge_gateway, Big\-Ip_fraud_protection_service, Big\-Ip_global_traffic_manager, Big\-Ip_link_controller, Big\-Ip_local_traffic_manager, Big\-Ip_policy_enforcement_manager, Big\-Ip_webaccelerator, Linux_kernel, Enterprise_linux, Enterprise_linux_desktop, Enterprise_linux_server, Enterprise_linux_server_aus, Enterprise_linux_server_eus, Enterprise_linux_server_tus, Enterprise_linux_workstation, Openshift_container_platform
|
8.1
|
|
|
2019-03-25
|
CVE-2019-3857
|
An integer overflow flaw which could lead to an out of bounds write was discovered in libssh2 before 1.8.1 in the way SSH_MSG_CHANNEL_REQUEST packets with an exit signal are parsed. A remote attacker who compromises a SSH server may be able to execute code on the client system when a user connects to the server.
|
Debian_linux, Fedora, Libssh2, Ontap_select_deploy_administration_utility, Leap, Peoplesoft_enterprise_peopletools, Enterprise_linux, Enterprise_linux_desktop, Enterprise_linux_server, Enterprise_linux_server_aus, Enterprise_linux_server_eus, Enterprise_linux_server_tus, Enterprise_linux_workstation
|
8.8
|
|
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