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張 旭

Outbound connections in Azure | Microsoft Docs - 0 views

docs.microsoft.com/...-balancer-outbound-connections

microsoft azure networking network

shared by 張 旭 on 15 Jul 19 - No Cached
  • When an instance initiates an outbound flow to a destination in the public IP address space, Azure dynamically maps the private IP address to a public IP address.
  • After this mapping is created, return traffic for this outbound originated flow can also reach the private IP address where the flow originated.
  • Azure uses source network address translation (SNAT) to perform this function
  • ...22 more annotations...
  • When multiple private IP addresses are masquerading behind a single public IP address, Azure uses port address translation (PAT) to masquerade private IP addresses.
  • If you want outbound connectivity when working with Standard SKUs, you must explicitly define it either with Standard Public IP addresses or Standard public Load Balancer.
  • the VM is part of a public Load Balancer backend pool. The VM does not have a public IP address assigned to it.
  • The Load Balancer resource must be configured with a load balancer rule to create a link between the public IP frontend with the backend pool.
  • VM has an Instance Level Public IP (ILPIP) assigned to it. As far as outbound connections are concerned, it doesn't matter whether the VM is load balanced or not.
  • When an ILPIP is used, the VM uses the ILPIP for all outbound flows.
  • A public IP assigned to a VM is a 1:1 relationship (rather than 1: many) and implemented as a stateless 1:1 NAT.
  • Port masquerading (PAT) is not used, and the VM has all ephemeral ports available for use.
  • When the load-balanced VM creates an outbound flow, Azure translates the private source IP address of the outbound flow to the public IP address of the public Load Balancer frontend.
  • Azure uses SNAT to perform this function. Azure also uses PAT to masquerade multiple private IP addresses behind a public IP address.
  • Ephemeral ports of the load balancer's public IP address frontend are used to distinguish individual flows originated by the VM.
  • When multiple public IP addresses are associated with Load Balancer Basic, any of these public IP addresses are a candidate for outbound flows, and one is selected at random.
  • the VM is not part of a public Load Balancer pool (and not part of an internal Standard Load Balancer pool) and does not have an ILPIP address assigned to it.
  • The public IP address used for this outbound flow is not configurable and does not count against the subscription's public IP resource limit.
  • Do not use this scenario for whitelisting IP addresses.
  • This public IP address does not belong to you and cannot be reserved.
  • Standard Load Balancer uses all candidates for outbound flows at the same time when multiple (public) IP frontends is present.
  • Load Balancer Basic chooses a single frontend to be used for outbound flows when multiple (public) IP frontends are candidates for outbound flows.
  • the disableOutboundSnat option defaults to false and signifies that this rule programs outbound SNAT for the associated VMs in the backend pool of the load balancing rule.
  • Port masquerading SNAT (PAT)
  • Ephemeral port preallocation for port masquerading SNAT (PAT)
  • determine the public source IP address of an outbound connection.
張 旭

Cluster Networking - Kubernetes - 0 views

kubernetes.io/...networking

kubernetes networking network system

shared by 張 旭 on 08 Jul 19 - No Cached
  • Networking is a central part of Kubernetes, but it can be challenging to understand exactly how it is expected to work
  • Highly-coupled container-to-container communications
  • Pod-to-Pod communications
  • ...57 more annotations...
  • this is the primary focus of this document
    • 張 旭
      張 旭 on 27 Aug 21
       
      Cluster Networking 所關注處理的是: Pod 到 Pod 之間的連線
  • Pod-to-Service communications
  • External-to-Service communications
  • Kubernetes is all about sharing machines between applications.
  • sharing machines requires ensuring that two applications do not try to use the same ports.
  • Dynamic port allocation brings a lot of complications to the system
  • Every Pod gets its own IP address
  • do not need to explicitly create links between Pods
  • almost never need to deal with mapping container ports to host ports.
  • Pods can be treated much like VMs or physical hosts from the perspectives of port allocation, naming, service discovery, load balancing, application configuration, and migration.
  • pods on a node can communicate with all pods on all nodes without NAT
  • agents on a node (e.g. system daemons, kubelet) can communicate with all pods on that node
  • pods in the host network of a node can communicate with all pods on all nodes without NAT
  • If your job previously ran in a VM, your VM had an IP and could talk to other VMs in your project. This is the same basic model.
  • containers within a Pod share their network namespaces - including their IP address
  • containers within a Pod can all reach each other’s ports on localhost
  • containers within a Pod must coordinate port usage
  • “IP-per-pod” model.
  • request ports on the Node itself which forward to your Pod (called host ports), but this is a very niche operation
  • The Pod itself is blind to the existence or non-existence of host ports.
  • AOS is an Intent-Based Networking system that creates and manages complex datacenter environments from a simple integrated platform.
  • Cisco Application Centric Infrastructure offers an integrated overlay and underlay SDN solution that supports containers, virtual machines, and bare metal servers.
  • AOS Reference Design currently supports Layer-3 connected hosts that eliminate legacy Layer-2 switching problems.
  • The AWS VPC CNI offers integrated AWS Virtual Private Cloud (VPC) networking for Kubernetes clusters.
  • users can apply existing AWS VPC networking and security best practices for building Kubernetes clusters.
  • Using this CNI plugin allows Kubernetes pods to have the same IP address inside the pod as they do on the VPC network.
  • The CNI allocates AWS Elastic Networking Interfaces (ENIs) to each Kubernetes node and using the secondary IP range from each ENI for pods on the node.
  • Big Cloud Fabric is a cloud native networking architecture, designed to run Kubernetes in private cloud/on-premises environments.
  • Cilium is L7/HTTP aware and can enforce network policies on L3-L7 using an identity based security model that is decoupled from network addressing.
  • CNI-Genie is a CNI plugin that enables Kubernetes to simultaneously have access to different implementations of the Kubernetes network model in runtime.
  • CNI-Genie also supports assigning multiple IP addresses to a pod, each from a different CNI plugin.
  • cni-ipvlan-vpc-k8s contains a set of CNI and IPAM plugins to provide a simple, host-local, low latency, high throughput, and compliant networking stack for Kubernetes within Amazon Virtual Private Cloud (VPC) environments by making use of Amazon Elastic Network Interfaces (ENI) and binding AWS-managed IPs into Pods using the Linux kernel’s IPvlan driver in L2 mode.
  • to be straightforward to configure and deploy within a VPC
  • Contiv provides configurable networking
  • Contrail, based on Tungsten Fabric, is a truly open, multi-cloud network virtualization and policy management platform.
  • DANM is a networking solution for telco workloads running in a Kubernetes cluster.
  • Flannel is a very simple overlay network that satisfies the Kubernetes requirements.
  • Any traffic bound for that subnet will be routed directly to the VM by the GCE network fabric.
  • sysctl net.ipv4.ip_forward=1
  • Jaguar provides overlay network using vxlan and Jaguar CNIPlugin provides one IP address per pod.
  • Knitter is a network solution which supports multiple networking in Kubernetes.
  • Kube-OVN is an OVN-based kubernetes network fabric for enterprises.
  • Kube-router provides a Linux LVS/IPVS-based service proxy, a Linux kernel forwarding-based pod-to-pod networking solution with no overlays, and iptables/ipset-based network policy enforcer.
  • If you have a “dumb” L2 network, such as a simple switch in a “bare-metal” environment, you should be able to do something similar to the above GCE setup.
  • Multus is a Multi CNI plugin to support the Multi Networking feature in Kubernetes using CRD based network objects in Kubernetes.
  • NSX-T can provide network virtualization for a multi-cloud and multi-hypervisor environment and is focused on emerging application frameworks and architectures that have heterogeneous endpoints and technology stacks.
  • NSX-T Container Plug-in (NCP) provides integration between NSX-T and container orchestrators such as Kubernetes
  • Nuage uses the open source Open vSwitch for the data plane along with a feature rich SDN Controller built on open standards.
  • OpenVSwitch is a somewhat more mature but also complicated way to build an overlay network
  • OVN is an opensource network virtualization solution developed by the Open vSwitch community.
  • Project Calico is an open source container networking provider and network policy engine.
  • Calico provides a highly scalable networking and network policy solution for connecting Kubernetes pods based on the same IP networking principles as the internet
  • Calico can be deployed without encapsulation or overlays to provide high-performance, high-scale data center networking.
  • Calico can also be run in policy enforcement mode in conjunction with other networking solutions such as Flannel, aka canal, or native GCE, AWS or Azure networking.
  • Romana is an open source network and security automation solution that lets you deploy Kubernetes without an overlay network
  • Weave Net runs as a CNI plug-in or stand-alone. In either version, it doesn’t require any configuration or extra code to run, and in both cases, the network provides one IP address per pod - as is standard for Kubernetes.
  • The network model is implemented by the container runtime on each node.
張 旭

MetalLB, bare metal load-balancer for Kubernetes - 0 views

metallb.universe.tf/concepts

kubernetes network

shared by 張 旭 on 14 Apr 21 - No Cached
  • it allows you to create Kubernetes services of type “LoadBalancer” in clusters that don’t run on a cloud provider
  • In a cloud-enabled Kubernetes cluster, you request a load-balancer, and your cloud platform assigns an IP address to you.
  • MetalLB cannot create IP addresses out of thin air, so you do have to give it pools of IP addresses that it can use.
  • ...6 more annotations...
  • MetalLB lets you define as many address pools as you want, and doesn’t care what “kind” of addresses you give it.
  • Once MetalLB has assigned an external IP address to a service, it needs to make the network beyond the cluster aware that the IP “lives” in the cluster.
  • In layer 2 mode, one machine in the cluster takes ownership of the service, and uses standard address discovery protocols (ARP for IPv4, NDP for IPv6) to make those IPs reachable on the local network
  • From the LAN’s point of view, the announcing machine simply has multiple IP addresses.
  • In BGP mode, all machines in the cluster establish BGP peering sessions with nearby routers that you control, and tell those routers how to forward traffic to the service IPs.
  • Using BGP allows for true load balancing across multiple nodes, and fine-grained traffic control thanks to BGP’s policy mechanisms.
張 旭

Service | Kubernetes - 0 views

kubernetes.io/...service

kubernetes networking service ingress

shared by 張 旭 on 14 Apr 21 - No Cached
  • Each Pod gets its own IP address
  • Pods are nonpermanent resources.
  • Kubernetes Pods are created and destroyed to match the state of your cluster
  • ...23 more annotations...
  • In Kubernetes, a Service is an abstraction which defines a logical set of Pods and a policy by which to access them (sometimes this pattern is called a micro-service).
  • The set of Pods targeted by a Service is usually determined by a selector
  • If you're able to use Kubernetes APIs for service discovery in your application, you can query the API server for Endpoints, that get updated whenever the set of Pods in a Service changes.
  • A Service in Kubernetes is a REST object, similar to a Pod.
  • The name of a Service object must be a valid DNS label name
  • Kubernetes assigns this Service an IP address (sometimes called the "cluster IP"), which is used by the Service proxies
  • A Service can map any incoming port to a targetPort. By default and for convenience, the targetPort is set to the same value as the port field.
  • The default protocol for Services is TCP
  • As many Services need to expose more than one port, Kubernetes supports multiple port definitions on a Service object. Each port definition can have the same protocol, or a different one.
  • Because this Service has no selector, the corresponding Endpoints object is not created automatically. You can manually map the Service to the network address and port where it's running, by adding an Endpoints object manually
  • Endpoint IP addresses cannot be the cluster IPs of other Kubernetes Services
  • Kubernetes ServiceTypes allow you to specify what kind of Service you want. The default is ClusterIP
  • ClusterIP: Exposes the Service on a cluster-internal IP.
  • NodePort: Exposes the Service on each Node's IP at a static port (the NodePort). A ClusterIP Service, to which the NodePort Service routes, is automatically created. You'll be able to contact the NodePort Service, from outside the cluster, by requesting <NodeIP>:<NodePort>.
  • LoadBalancer: Exposes the Service externally using a cloud provider's load balancer
  • ExternalName: Maps the Service to the contents of the externalName field (e.g. foo.bar.example.com), by returning a CNAME record with its value. No proxying of any kind is set up.
  • You can also use Ingress to expose your Service. Ingress is not a Service type, but it acts as the entry point for your cluster.
  • If you set the type field to NodePort, the Kubernetes control plane allocates a port from a range specified by --service-node-port-range flag (default: 30000-32767).
  • The default for --nodeport-addresses is an empty list. This means that kube-proxy should consider all available network interfaces for NodePort.
  • you need to take care of possible port collisions yourself. You also have to use a valid port number, one that's inside the range configured for NodePort use.
  • Service is visible as <NodeIP>:spec.ports[*].nodePort and .spec.clusterIP:spec.ports[*].port
  • Choosing this value makes the Service only reachable from within the cluster.
  • NodePort: Exposes the Service on each Node's IP at a static port
張 旭

一位开发者的 Linux 容器之旅 - 51CTO.COM - 0 views

developer.51cto.com/...497798.htm

docker linux container system development devops

shared by 張 旭 on 22 Nov 15 - No Cached
  • 容器是一个 Linux 进程,Linux 认为它只是一个运行中的进程。该进程只知道它被告知的东西。
  • 容器进程也分配了它自己的 IP 地址
  • 和典型虚拟机的静态方式不同。所有这些资源的共享都由容器管理器来管理。
  • ...26 more annotations...
  • 可以在容器管理器上运行命令,使容器 IP 映射到主机中能访问公网的 IP 地址。建立了该映射,无论出于什么意图和目的,容器就是网络上一个可访问的独立机器,从概念上类似于虚拟机。
  • 容器是拥有不同 IP 地址从而使其成为网络上可识别的独立 Linux 进程
  • 容器/进程以动态、合作的方式共享主机上的资源。
  • 容器能非常快速地启动
  • 操作系统被所有容器所共享,减少了容器足迹的重复和冗余。每个容器只包括该容器特有的部分
  • 获得了虚拟机独立和封装的好处,而抛弃了静态资源专有的缺陷
  • 托管容器的计算机运行着被剥离的只剩下主要部分的某个 Linux 版本
  • Ubuntu Snappy
  • Red Hat Atomic Host
  • CoreOS
  • 在容器化方面,容器进程有它自己的 IP 地址。一旦给予了一个 IP 地址,该进程就是宿主网络中可识别的资源
  • 一个容器组件被称为层(layer)
  • 层是一个容器镜像
  • 容器管理器只提供你所要的操作系统在宿主操作系统中不存在的部分
  • 在容器配置文件中重新定义层
  • 容器的各种功能都由一个称为容器管理器(container manager)的软件控制
  • Docker
  • Rocket
  • 镜像存储在注册库(registry)中,注册库通过网络访问
  • 注册库类似于一个使用 Java 的人眼中的 Maven 仓库、使用 .NET 的人眼中的 NuGet 服务器。
  • 容器管理器会封装你应用程序的所有东西为一个独立容器,该容器将会在容器管理器的管理下运行在宿主计算机上。
  • 每个容器有一个独立的 IP 地址
  • 在一个负载均衡容器后运行容器集群以获得更高的性能和高可用计算
  • Deis 的容器配置技术
  • 每次添加实例到环境中时,你不需要手动配置负载均衡器以便接受你的容器镜像。
  • 使用服务发现技术让容器告知均衡器它可用
張 旭

一位开发者的 Linux 容器之旅-技术 ◆ 学习|Linux.中国-开源社区 - 1 views

linux.cn/article-6594-1.html

linux docker container system development devops

shared by 張 旭 on 22 Nov 15 - No Cached
  • 容器是一个 Linux 进程,Linux 认为它只是一个运行中的进程。该进程只知道它被告知的东西。
  • 容器进程也分配了它自己的 IP 地址。
  • 在容器化方面,容器进程有它自己的 IP 地址。一旦给予了一个 IP 地址,该进程就是宿主网络中可识别的资源
  • ...20 more annotations...
  • 使容器 IP 映射到主机中能访问公网的 IP 地址。建立了该映射,无论出于什么意图和目的,容器就是网络上一个可访问的独立机器,从概念上类似于虚拟机。
  • 容器是拥有不同 IP 地址从而使其成为网络上可识别的独立 Linux 进程
  • CPU、内存和存储空间的分配是动态的,和典型虚拟机的静态方式不同。所有这些资源的共享都由容器管理器来管理。
  • 容器能非常快速地启动
  • 托管容器的计算机运行着被剥离的只剩下主要部分的某个 Linux 版本。
  • 操作系统被所有容器所共享,减少了容器足迹的重复和冗余。每个容器只包括该容器特有的部分
  • 层是一个容器镜像
  • 一个容器组件被称为层(layer)
  • 容器的各种功能都由一个称为容器管理器(container manager)的软件控制
  • 流行的容器管理器是 Docker 和 Rocket
  • 镜像存储在注册库(registry)中,注册库通过网络访问
  • 镜像代表了你的容器需要完成其工作的容器模板
  • 应用程序所需镜像的容器配置文件
  • 每个容器有一个独立的 IP 地址。因此,能把它放到负载均衡器后面。将容器放到负载均衡器后面,这就上升了一个层面。
  • Deis 的容器配置技术
  • 可以部署一个或多个容器镜像到主机上的负载均衡器下
  • 每次添加实例到环境中时,你不需要手动配置负载均衡器以便接受你的容器镜像。你可以使用服务发现技术让容器告知均衡器它可用。
  • 类似 CoreOS、RHEL Atomic、和 Ubuntu 的 Snappy 宿主操作系统
  • 类似 Docker 和 Rocket 的容器管理技术结合起来
  • 类似 Deis 这样的配置技术使容器创建和部署变得更加简单
張 旭

Understanding Nginx Server and Location Block Selection Algorithms | DigitalOcean - 0 views

www.digitalocean.com/...ion-block-selection-algorithms

web server nginx config

shared by 張 旭 on 03 Feb 20 - No Cached
  • A server block is a subset of Nginx’s configuration that defines a virtual server used to handle requests of a defined type. Administrators often configure multiple server blocks and decide which block should handle which connection based on the requested domain name, port, and IP address.
  • A location block lives within a server block and is used to define how Nginx should handle requests for different resources and URIs for the parent server. The URI space can be subdivided in whatever way the administrator likes using these blocks. It is an extremely flexible model.
  • Nginx logically divides the configurations meant to serve different content into blocks, which live in a hierarchical structure. Each time a client request is made, Nginx begins a process of determining which configuration blocks should be used to handle the request.
  • ...37 more annotations...
  • Nginx is one of the most popular web servers in the world. It can successfully handle high loads with many concurrent client connections, and can easily function as a web server, a mail server, or a reverse proxy server.
  • The main server block directives that Nginx is concerned with during this process are the listen directive, and the server_name directive.
  • The listen directive typically defines which IP address and port that the server block will respond to.
  • 0.0.0.0:8080 if Nginx is being run by a normal, non-root user
  • Nginx translates all “incomplete” listen directives by substituting missing values with their default values so that each block can be evaluated by its IP address and port.
  • In any case, the port must be matched exactly.
  • If there are multiple server blocks with the same level of specificity matching, Nginx then begins to evaluate the server_name directive of each server block.
  • Nginx will only evaluate the server_name directive when it needs to distinguish between server blocks that match to the same level of specificity in the listen directive.
  • Nginx checks the request’s “Host” header. This value holds the domain or IP address that the client was actually trying to reach.
  • Nginx will first try to find a server block with a server_name that matches the value in the “Host” header of the request exactly.
  • If no exact match is found, Nginx will then try to find a server block with a server_name that matches using a leading wildcard (indicated by a * at the beginning of the name in the config).
  • If no match is found using a leading wildcard, Nginx then looks for a server block with a server_name that matches using a trailing wildcard (indicated by a server name ending with a * in the config)
  • If no match is found using a trailing wildcard, Nginx then evaluates server blocks that define the server_name using regular expressions (indicated by a ~ before the name).
  • If no regular expression match is found, Nginx then selects the default server block for that IP address and port.
  • There can be only one default_server declaration per each IP address/port combination.
  • Location blocks live within server blocks (or other location blocks) and are used to decide how to process the request URI (the part of the request that comes after the domain name or IP address/port).
  • If no modifiers are present, the location is interpreted as a prefix match.
  • =: If an equal sign is used, this block will be considered a match if the request URI exactly matches the location given.
  • ~: If a tilde modifier is present, this location will be interpreted as a case-sensitive regular expression match.
  • ~*: If a tilde and asterisk modifier is used, the location block will be interpreted as a case-insensitive regular expression match.
  • ^~: If a carat and tilde modifier is present, and if this block is selected as the best non-regular expression match, regular expression matching will not take place.
  • Keep in mind that if this block is selected and the request is fulfilled using an index page, an internal redirect will take place to another location that will be the actual handler of the request
  • Keeping in mind the types of location declarations we described above, Nginx evaluates the possible location contexts by comparing the request URI to each of the locations.
  • Nginx begins by checking all prefix-based location matches (all location types not involving a regular expression).
  • First, Nginx looks for an exact match.
  • If no exact (with the = modifier) location block matches are found, Nginx then moves on to evaluating non-exact prefixes.
  • After the longest matching prefix location is determined and stored, Nginx moves on to evaluating the regular expression locations (both case sensitive and insensitive).
  • by default, Nginx will serve regular expression matches in preference to prefix matches.
  • regular expression matches within the longest prefix match will “jump the line” when Nginx evaluates regex locations.
  • The exceptions to the “only one location block” rule may have implications on how the request is actually served and may not align with the expectations you had when designing your location blocks.
  • The index directive always leads to an internal redirect if it is used to handle the request.
  • In the case above, if you really need the execution to stay in the first block, you will have to come up with a different method of satisfying the request to the directory.
  • one way of preventing an index from switching contexts, but it’s probably not useful for most configurations
  • the try_files directive. This directive tells Nginx to check for the existence of a named set of files or directories.
  • the rewrite directive. When using the last parameter with the rewrite directive, or when using no parameter at all, Nginx will search for a new matching location based on the results of the rewrite.
  • The error_page directive can lead to an internal redirect similar to that created by try_files.
  • when certain status codes are encountered.
張 旭

Warnings, Notes, & Tips - 0 views

clouddocs.f5.com/...tips-warnings.html

terraform networking network firewall bigip

shared by 張 旭 on 04 May 20 - No Cached
  • AS3 manages topology records globally in /Common, it is required that records only be managed through AS3, as it will treat the records declaratively.
  • If a record is added outside of AS3, it will be removed if it is not included in the next AS3 declaration for topology records (AS3 completely overwrites non-AS3 topologies when a declaration is submitted).
  • using AS3 to delete a tenant (for example, sending DELETE to the /declare/<TENANT> endpoint) that contains GSLB topologies will completely remove ALL GSLB topologies from the BIG-IP.
  • ...12 more annotations...
  • When posting a large declaration (hundreds of application services in a single declaration), you may experience a 500 error stating that the save sys config operation failed.
  • Even if you have asynchronous mode set to false, after 45 seconds AS3 sets asynchronous mode to true (API swap), and returns an async response.
  • When creating a new tenant using AS3, it must not use the same name as a partition you separately create on the target BIG-IP system.
  • If you use the same name and then post the declaration, AS3 overwrites (or removes) the existing partition completely, including all configuration objects in that partition.
  • use AS3 to create a tenant (which creates a BIG-IP partition), manually adding configuration objects to the partition created by AS3 can have unexpected results
  • When you delete the Tenant using AS3, the system deletes both virtual servers.
  • if a Firewall_Address_List contains zero addresses, a dummy IPv6 address of ::1:5ee:bad:c0de is added in order to maintain a valid Firewall_Address_List. If an address is added to the list, the dummy address is removed.
  • use /mgmt/shared/appsvcs/declare?async=true if you have a particularly large declaration which will take a long time to process.
  • reviewing the Sizing BIG-IP Virtual Editions section (page 7) of Deploying BIG-IP VEs in a Hyper-Converged Infrastructure
  • To test whether your system has AS3 installed or not, use GET with the /mgmt/shared/appsvcs/info URI.
  • You may find it more convenient to put multi-line texts such as iRules into AS3 declarations by first encoding them in Base64.
  • no matter your BIG-IP user account name, audit logs show all messages from admin and not the specific user name.
張 旭

kubernetes 简介:service 和 kube-proxy 原理 | Cizixs Write Here - 0 views

cizixs.com/...duction-service-and-kube-proxy

kubernetes system networking

shared by 張 旭 on 01 Jul 21 - No Cached
  • kubernetes 对网络的要求是:容器之间(包括同一台主机上的容器,和不同主机的容器)可以互相通信,容器和集群中所有的节点也能直接通信。
  • 跨主机网络配置:flannel
  • flannel 也能够通过 CNI 插件的形式使用。
  • ...8 more annotations...
  • 从集群中获取每个 pod ip 地址,然后也能在集群内部直接通过 podIP:Port 来获取对应的服务。
  • pod 是经常变化的,每次更新 ip 地址都可能会发生变化,如果直接访问容器 ip 的话,会有很大的问题。
  • “服务”(service),每个服务都一个固定的虚拟 ip(这个 ip 也被称为 cluster IP),自动并且动态地绑定后面的 pod,所有的网络请求直接访问服务 ip,服务会自动向后端做转发。
  • 实现 service 这一功能的关键,就是 kube-proxy。
  • kube-proxy 运行在每个节点上,监听 API Server 中服务对象的变化,通过管理 iptables 来实现网络的转发。
  • kube-proxy 要求 NODE 节点操作系统中要具备 /sys/module/br_netfilter 文件,而且还要设置 bridge-nf-call-iptables=1
  • iptables 完全实现 iptables 来实现 service,是目前默认的方式,也是推荐的方式,效率很高(只有内核中 netfilter 一些损耗)。
  • 可以在终端上启动 kube-proxy,也可以使用诸如 systemd 这样的工具来管理它
crazylion lee

pytbull - IDS/IPS Testing Framework - home - 0 views

pytbull.sourceforge.net/index.php

ids ips opensource attack

shared by crazylion lee on 12 May 16 - No Cached
  • crazylion lee on 12 May 16
     
    "You've just set up your Intrusion Detection/Prevention System (IDS/IPS) and feel "Now I'm secure". But how can you be so sure? And how much do you trust your IDS/IPS? "
張 旭

Introducing CNAME Flattening: RFC-Compliant CNAMEs at a Domain's Root - 0 views

blog.cloudflare.com/liant-cnames-at-a-domains-root

dns networking

shared by 張 旭 on 15 Mar 22 - No Cached
  • you can now safely use a CNAME record, as opposed to an A record that points to a fixed IP address, as your root record in CloudFlare DNS without triggering a number of edge case error conditions because you’re violating the DNS spec.
  • CNAME Flattening allowed us to use a root domain while still maintaining DNS fault-tolerance across multiple IP addresses.
  • Traditionally, the root record of a domain needed to point to an IP address (known as an A -- for "address" -- Record).
  • ...13 more annotations...
  • WordPlumblr allows its users to use custom domains that point to the WordPlumblr infrastructure
  • A CNAME is an alias. It allows one domain to point to another domain which, eventually if you follow the CNAME chain, will resolve to an A record and IP address.
  • For example, WordPlumblr might have assigned the CNAME 6equj5.wordplumblr.com for Foo.com. Foo.com and the other customers may have all initially resolved, at the end of the CNAME chain, to the same IP address.
  • you usually don't want to address memory directly but, instead, you set up a pointer to a block of memory where you're going to store something. If the operating system needs to move the memory around then it just updates the pointer to point to wherever the chunk of memory has been moved to.
  • CNAMEs work great for subdomains like www.foo.com or blog.foo.com. Unfortunately, they don't work for a naked domain like foo.com itself.
  • the DNS spec enshrined that the root record -- the naked domain without any subdomain -- could not be a CNAME.
  • Technically, the root could be a CNAME but the RFCs state that once a record has a CNAME it can't have any other entries associated with it
  • a way to support a CNAME at the root, but still follow the RFC and return an IP address for any query for the root record.
  • extended our authoritative DNS infrastructure to, in certain cases, act as a kind of DNS resolver.
  • if there's a CNAME at the root, rather than returning that record directly we recurse through the CNAME chain ourselves until we find an A Record.
  • allows the flexibility of having CNAMEs at the root without breaking the DNS specification.
  • We cache the CNAME responses -- respecting the DNS TTLs, just like a recursor should -- which means often we have the answer without having to traverse the chain.
  • CNAME flattening solved email resolution errors for us which was very key.
張 旭

VPCs and Subnets - Amazon Virtual Private Cloud - 0 views

docs.aws.amazon.com/...VPC_Subnets.html

aws networking amazon cloud

shared by 張 旭 on 31 Jul 18 - No Cached
  • you must specify a range of IPv4 addresses for the VPC in the form of a Classless Inter-Domain Routing (CIDR) block
  • A VPC spans all the Availability Zones in the region
  • add one or more subnets in each Availability Zone.
  • ...19 more annotations...
  • Each subnet must reside entirely within one Availability Zone and cannot span zones.
  • Availability Zones are distinct locations that are engineered to be isolated from failures in other Availability Zones
  • If a subnet's traffic is routed to an internet gateway, the subnet is known as a public subnet.
  • If a subnet doesn't have a route to the internet gateway, the subnet is known as a private subnet.
  • If a subnet doesn't have a route to the internet gateway, but has its traffic routed to a virtual private gateway for a VPN connection, the subnet is known as a VPN-only subnet.
  • By default, all VPCs and subnets must have IPv4 CIDR blocks—you can't change this behavior.
  • The allowed block size is between a /16 netmask (65,536 IP addresses) and /28 netmask (16 IP addresses).
  • The first four IP addresses and the last IP address in each subnet CIDR block are not available for you to use
  • The allowed block size is between a /28 netmask and /16 netmask
  • The CIDR block must not overlap with any existing CIDR block that's associated with the VPC.
  • Each subnet must be associated with a route table
  • Every subnet that you create is automatically associated with the main route table for the VPC
  • Security groups control inbound and outbound traffic for your instances
  • network ACLs control inbound and outbound traffic for your subnets
  • each subnet must be associated with a network ACL
  • You can create a flow log on your VPC or subnet to capture the traffic that flows to and from the network interfaces in your VPC or subnet.
  • A VPC peering connection enables you to route traffic between the VPCs using private IP addresses
  • you cannot create a VPC peering connection between VPCs that have overlapping CIDR blocks
  • recommend that you create a VPC with a CIDR range large enough for expected future growth, but not one that overlaps with current or expected future subnets anywhere in your corporate or home network, or that overlaps with current or future VPCs
張 旭

DNS Records: an Introduction - 0 views

linode.com/...dns-records-an-introduction

dns server networking

shared by 張 旭 on 26 Mar 18 - No Cached
  • reading from right to left
  • top-level domain, or TLD
  • first-level subdomains plus their TLDs (example.com) are referred to as “domains.”
  • ...37 more annotations...
  • Name servers host a domain’s DNS information in a text file called the zone file
  • Start of Authority (SOA) records
  • You’ll want to specify at least two name servers. That way, if one of them is down, the next one can continue to serve your DNS information.
  • Every domain’s zone file contains the admin’s email address, the name servers, and the DNS records.
  • a zone file, which lists domains and their corresponding IP addresses (and a few other things)
  • TLD nameserver
  • ISPs cache a lot of DNS information after they’ve looked it up the first time
  • Usually caching is a good thing, but it can be a problem if you’ve recently made a change to your DNS information
  • An A record matches up a domain (or subdomain) to an IP address
  • point different subdomains to different IP addresses
  • An AAAA record is just like an A record, but for IPv6 IP addresses.
  • An AXFR record is a type of DNS record used for DNS replication
  • used on a slave DNS server to replicate the zone file from a master DNS server
  • DNS Certification Authority Authorization uses DNS to allow the holder of a domain to specify which certificate authorities are allowed to issue certificates for that domain.
  • A CNAME record or Canonical Name record matches up a domain (or subdomain) to a different domain.
  • You should not use a CNAME record for a domain that gets email, because some mail servers handle mail oddly for domains with CNAME records
  • the target domain for a CNAME record should have a normal A-record resolution
  • a CNAME record does not function the same way as a URL redirect
  • A DKIM record or domain keys identified mail record displays the public key for authenticating messages that have been signed with the DKIM protocol
  • An MX record or mail exchange record sets the mail delivery destination for a domain (or subdomain).
  • Ideally, an MX record should point to a domain that is also the hostname for its server.
  • Your MX records don’t necessarily have to point to your Linode. If you’re using a third-party mail service, like Google Apps, you should use the MX records they provide.
  • Lower numbers have a higher priority
  • NS records or name server records set the nameservers for a domain (or subdomain).
  • You can also set up different nameservers for any of your subdomains.
  • The order of NS records does not matter; DNS requests are sent randomly to the different servers, and if one host fails to respond, another one will be queried.
  • A PTR record or pointer record matches up an IP address to a domain (or subdomain), allowing reverse DNS queries to function.
  • PTR records are usually set with your hosting provider. They are not part of your domain’s zone file.
  • An SOA record or Start of Authority record labels a zone file with the name of the host where it was originally created.
  • The administrative email address is written with a period (.) instead of an at symbol (<@>).
  • The single nameserver mentioned in the SOA record is considered the primary master for the purposes of Dynamic DNS and is the server where zone file changes get made before they are propagated to all other nameservers.
  • An SPF record or Sender Policy Framework record lists the designated mail servers for a domain (or subdomain).
  • An SPF record for your domain tells other receiving mail servers which outgoing server(s) are valid sources of email, so they can reject spoofed email from your domain that has originated from unauthorized servers.
  • Your SPF record will have a domain or subdomain, type (which is TXT, or SPF if your name server supports it), and text (which starts with “v=spf1” and contains the SPF record settings).
  • An SRV record or service record matches up a specific service that runs on your domain (or subdomain) to a target domain.
  • A TXT record or text record provides information about the domain in question to other resources on the Internet.
  • One common use of the TXT record is to create an SPF record on nameservers that don’t natively support SPF.
張 旭

DNS Records: An Introduction - 0 views

www.linode.com/...dns-records-an-introduction

dns networking system

shared by 張 旭 on 28 Aug 19 - No Cached
  • Domain names are best understood by reading from right to left.
  • the top-level domain, or TLD
  • Every term to the left of the TLD is separated by a period and considered a more specific subdomain
  • ...40 more annotations...
  • Name servers host a domain’s DNS information in a text file called a zone file.
  • Start of Authority (SOA) records
  • specifying DNS records, which match domain names to IP addresses.
  • Every domain’s zone file contains the domain administrator’s email address, the name servers, and the DNS records.
  • Your ISP’s DNS resolver queries a root nameserver for the proper TLD nameserver. In other words, it asks the root nameserver, *Where can I find the nameserver for .com domains?*
  • In actuality, ISPs cache a lot of DNS information after they’ve looked it up the first time.
  • caching is a good thing, but it can be a problem if you’ve recently made a change to your DNS information
  • An A record points your domain or subdomain to your Linode’s IP address,
  • use an asterisk (*) as your subdomain
  • An AAAA record is just like an A record, but for IPv6 IP addresses.
  • An AXFR record is a type of DNS record used for DNS replication
  • DNS Certification Authority Authorization uses DNS to allow the holder of a domain to specify which certificate authorities are allowed to issue certificates for that domain.
  • A CNAME record or Canonical Name record matches a domain or subdomain to a different domain.
  • Some mail servers handle mail oddly for domains with CNAME records, so you should not use a CNAME record for a domain that gets email.
  • MX records cannot reference CNAME-defined hostnames.
  • Chaining or looping CNAME records is not recommended.
  • a CNAME record does not function the same way as a URL redirect.
  • A DKIM record or DomainKeys Identified Mail record displays the public key for authenticating messages that have been signed with the DKIM protocol
  • DKIM records are implemented as text records.
  • An MX record or mail exchanger record sets the mail delivery destination for a domain or subdomain.
  • An MX record should ideally point to a domain that is also the hostname for its server.
  • Priority allows you to designate a fallback server (or servers) for mail for a particular domain. Lower numbers have a higher priority.
  • NS records or name server records set the nameservers for a domain or subdomain.
  • You can also set up different nameservers for any of your subdomains
  • Primary nameservers get configured at your registrar and secondary subdomain nameservers get configured in the primary domain’s zone file.
  • The order of NS records does not matter. DNS requests are sent randomly to the different servers
  • A PTR record or pointer record matches up an IP address to a domain or subdomain, allowing reverse DNS queries to function.
  • opposite service an A record does
  • PTR records are usually set with your hosting provider. They are not part of your domain’s zone file.
  • An SOA record or Start of Authority record labels a zone file with the name of the host where it was originally created.
  • Minimum TTL: The minimum amount of time other servers should keep data cached from this zone file.
  • An SPF record or Sender Policy Framework record lists the designated mail servers for a domain or subdomain.
  • An SPF record for your domain tells other receiving mail servers which outgoing server(s) are valid sources of email so they can reject spoofed mail from your domain that has originated from unauthorized servers.
  • Make sure your SPF records are not too strict.
  • An SRV record or service record matches up a specific service that runs on your domain or subdomain to a target domain.
  • Service: The name of the service must be preceded by an underscore (_) and followed by a period (.)
  • Protocol: The name of the protocol must be proceeded by an underscore (_) and followed by a period (.)
  • Port: The TCP or UDP port on which the service runs.
  • Target: The target domain or subdomain. This domain must have an A or AAAA record that resolves to an IP address.
  • A TXT record or text record provides information about the domain in question to other resources on the internet.
  • 張 旭 on 28 Aug 19
     
    "Domain names are best understood by reading from right to left."
張 旭

AskF5 | Manual Chapter: Working with Partitions - 0 views

techdocs.f5.com/...8.html

bigip network

shared by 張 旭 on 05 May 20 - No Cached
  • During BIG-IP® system installation, the system automatically creates a partition named Common
  • An administrative partition is a logical container that you create, containing a defined set of BIG-IP® system objects.
  • No user can delete partition Common itself.
  • ...9 more annotations...
  • With respect to permissions, all users on the system except those with a user role of No Access have read access to objects in partition Common, and by default, partition Common is their current partition.
  • The current partition is the specific partition to which the system is currently set for a logged-in user.
  • A partition access assignment gives a user some level of access to the specified partition.
  • assigning partition access to a user does not necessarily give the user full access to all objects in the partition
  • user account objects also reside in partitions
  • when you first install the BIG-IP system, every existing user account (root and admin) resides in partition Common
  • the partition in which a user account object resides does not affect the partition or partitions to which that user is granted access to manage other BIG-IP objects
  • the object it references resides in partition Common
  • a referenced object must reside either in the same partition as the object that is referencing it
張 旭

探索 Docker bridge 的正确姿势,亲测有效! | DaoCloud - 1 views

blog.daocloud.io/docker-bridge

docker networking system

shared by 張 旭 on 10 Mar 17 - No Cached
  • Docker bridge 和 Linux bridge 二者,初看如出一辙,再看又相去甚远
  • Linux bridge 模式下,Linux Kernel 会创建出一个虚拟网桥 ,用以实现主机网络接口与虚拟网络接口间的通信
  • Linux bridge 像一台虚拟交换机
  • ...15 more annotations...
  • Docker Daemon 会创建出一个名为 docker0 的虚拟网桥 ,用来连接宿主机与容器,或者连接不同的容器
  • veth pair 技术的特性可以保证无论哪一个 veth 接收到网络报文,都会无条件地传输给另一方
  • 在桥接模式下,Docker Daemon 将 veth0 附加到 docker0 网桥上,保证宿主机的报文有能力发往 veth0。
  • 将 veth1 添加到 Docker 容器所属的网络命名空间[注释2],保证宿主机的网络报文若发往 veth0 可以立即被 veth1 收到
  • NATP 包含两种转换方式:SNAT 和 DNAT
  • 目的 NAT (Destination NAT,DNAT): 修改数据包的目的地址
  • 容器的 IP 与端口对外都是不可见的
  • 数据包的目的地址为宿主机的 ip 和端口
  • 将数据包发送附加到 docker0 网桥上的 veth0 接口,veth0 接口再将数据包发送给容器内部的 veth1 接口,容器接收数据包并作出响应
  • 源 NAT (Source NAT,SNAT): 修改数据包的源地址
  • 宿主机上的 docker0 网桥发现数据包的目的地址为外界的 IP 和端口,便会将数据包转发给 eth0 ,并从 eth0 发出去。由于存在 SNAT 规则,会将数据包的源地址转换为宿主机的 ip 和端口
  • Docker 容器对外是不可见的
  • veth pair是用于不同network namespace间进行通信的方式,veth pair 将一个 network namespace 数据发往另一个 network namespace 的 veth
  • 网络命名空间是用于隔离网络资源(/proc/net、IP 地址、网卡、路由等)
  • NAT 为网络地址转换(Network Address Translation)的缩写
張 旭

Ingress - Kubernetes - 0 views

kubernetes.io/...ingress

kubernetes networking network ingress

shared by 張 旭 on 04 Jul 19 - No Cached
  • An API object that manages external access to the services in a cluster, typically HTTP.
  • load balancing
  • SSL termination
  • ...62 more annotations...
  • name-based virtual hosting
  • Edge routerA router that enforces the firewall policy for your cluster.
  • Cluster networkA set of links, logical or physical, that facilitate communication within a cluster according to the Kubernetes networking model.
  • A Kubernetes ServiceA way to expose an application running on a set of Pods as a network service. that identifies a set of Pods using labelTags objects with identifying attributes that are meaningful and relevant to users. selectors.
  • Services are assumed to have virtual IPs only routable within the cluster network.
  • Ingress exposes HTTP and HTTPS routes from outside the cluster to services within the cluster.
  • Traffic routing is controlled by rules defined on the Ingress resource.
  • An Ingress can be configured to give Services externally-reachable URLs, load balance traffic, terminate SSL / TLS, and offer name based virtual hosting.
  • Exposing services other than HTTP and HTTPS to the internet typically uses a service of type Service.Type=NodePort or Service.Type=LoadBalancer.
  • You must have an ingress controller to satisfy an Ingress. Only creating an Ingress resource has no effect.
  • As with all other Kubernetes resources, an Ingress needs apiVersion, kind, and metadata fields
  • Ingress frequently uses annotations to configure some options depending on the Ingress controller,
  • Ingress resource only supports rules for directing HTTP traffic.
  • An optional host.
  • A list of paths
  • A backend is a combination of Service and port names
  • has an associated backend
  • Both the host and path must match the content of an incoming request before the load balancer directs traffic to the referenced Service.
  • HTTP (and HTTPS) requests to the Ingress that matches the host and path of the rule are sent to the listed backend.
  • A default backend is often configured in an Ingress controller to service any requests that do not match a path in the spec.
  • An Ingress with no rules sends all traffic to a single default backend.
  • Ingress controllers and load balancers may take a minute or two to allocate an IP address.
  • A fanout configuration routes traffic from a single IP address to more than one Service, based on the HTTP URI being requested.
  • nginx.ingress.kubernetes.io/rewrite-target: /
  • describe ingress
  • get ingress
  • Name-based virtual hosts support routing HTTP traffic to multiple host names at the same IP address.
  • route requests based on the Host header.
  • an Ingress resource without any hosts defined in the rules, then any web traffic to the IP address of your Ingress controller can be matched without a name based virtual host being required.
  • secure an Ingress by specifying a SecretStores sensitive information, such as passwords, OAuth tokens, and ssh keys. that contains a TLS private key and certificate.
  • Currently the Ingress only supports a single TLS port, 443, and assumes TLS termination.
  • An Ingress controller is bootstrapped with some load balancing policy settings that it applies to all Ingress, such as the load balancing algorithm, backend weight scheme, and others.
  • persistent sessions, dynamic weights) are not yet exposed through the Ingress. You can instead get these features through the load balancer used for a Service.
  • review the controller specific documentation to see how they handle health checks
  • edit ingress
  • After you save your changes, kubectl updates the resource in the API server, which tells the Ingress controller to reconfigure the load balancer.
  • kubectl replace -f on a modified Ingress YAML file.
  • Node: A worker machine in Kubernetes, part of a cluster.
  • in most common Kubernetes deployments, nodes in the cluster are not part of the public internet.
  • Edge router: A router that enforces the firewall policy for your cluster.
  • a gateway managed by a cloud provider or a physical piece of hardware.
  • Cluster network: A set of links, logical or physical, that facilitate communication within a cluster according to the Kubernetes networking model.
  • Service: A Kubernetes Service that identifies a set of Pods using label selectors.
  • An Ingress may be configured to give Services externally-reachable URLs, load balance traffic, terminate SSL / TLS, and offer name-based virtual hosting.
  • An Ingress does not expose arbitrary ports or protocols.
  • You must have an Ingress controller to satisfy an Ingress. Only creating an Ingress resource has no effect.
  • The name of an Ingress object must be a valid DNS subdomain name
  • The Ingress spec has all the information needed to configure a load balancer or proxy server.
  • Ingress resource only supports rules for directing HTTP(S) traffic.
  • An Ingress with no rules sends all traffic to a single default backend and .spec.defaultBackend is the backend that should handle requests in that case.
  • If defaultBackend is not set, the handling of requests that do not match any of the rules will be up to the ingress controller
  • A common usage for a Resource backend is to ingress data to an object storage backend with static assets.
  • Exact: Matches the URL path exactly and with case sensitivity.
  • Prefix: Matches based on a URL path prefix split by /. Matching is case sensitive and done on a path element by element basis.
  • multiple paths within an Ingress will match a request. In those cases precedence will be given first to the longest matching path.
  • Hosts can be precise matches (for example “foo.bar.com”) or a wildcard (for example “*.foo.com”).
  • No match, wildcard only covers a single DNS label
  • Each Ingress should specify a class, a reference to an IngressClass resource that contains additional configuration including the name of the controller that should implement the class.
  • secure an Ingress by specifying a Secret that contains a TLS private key and certificate.
  • The Ingress resource only supports a single TLS port, 443, and assumes TLS termination at the ingress point (traffic to the Service and its Pods is in plaintext).
  • TLS will not work on the default rule because the certificates would have to be issued for all the possible sub-domains.
  • hosts in the tls section need to explicitly match the host in the rules section.
crazylion lee

The TCP/IP Guide - Introduction To The TCP/IP Guide - 0 views

www.tcpipguide.com/...ntroductionToTheTCPIPGuide.htm

tcp guide introduction

shared by crazylion lee on 17 Jun 16 - No Cached
  • crazylion lee on 17 Jun 16
     
    " Introduction To The TCP/IP Guide"
張 旭

Internet Gateways - Amazon Virtual Private Cloud - 0 views

docs.aws.amazon.com/...VPC_Internet_Gateway.html

aws networking system

shared by 張 旭 on 10 Jul 18 - No Cached
  • to provide a target in your VPC route tables for internet-routable traffic
  • to perform network address translation (NAT) for instances that have been assigned public IPv4 addresses
  • Ensure that instances in your subnet have a globally unique IP address (public IPv4 address, Elastic IP address, or IPv6 address)
  • ...10 more annotations...
  • To use an internet gateway, your subnet's route table must contain a route that directs internet-bound traffic to the internet gateway.
  • If your subnet is associated with a route table that has a route to an internet gateway, it's known as a public subnet.
  • To enable communication over the internet for IPv4, your instance must have a public IPv4 address or an Elastic IP address that's associated with a private IPv4 address on your instance.
  • Your instance is only aware of the private (internal) IP address space defined within the VPC and subnet
  • internet gateway logically provides the one-to-one NAT on behalf of your instance
  • To enable communication over the internet for IPv6, your VPC and subnet must have an associated IPv6 CIDR block, and your instance must be assigned an IPv6 address from the range of the subnet.
  • When you create a subnet, we automatically associate it with the main route table for the VPC.
  • the main route table doesn't contain a route to an internet gateway
  • Each instance that you launch into a VPC is automatically associated with its default security group.
  • a default security group allow no inbound traffic from the internet and allow all outbound traffic to the internet.
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