h3c-IRF配置指导-整本手册

H3C IRF配置典型案例●进入系统模式●切换IRF模式●配置成员编号●配置成员优先级●配置IRF端口●使能BFD MAD检测●使能LACP MAD检测●配置保留端口●手动恢复处于Recovery 状态的设备●重定向到指定的Slave 设备●IRF 显示和维护●配置举例（BFD/LACP MAD）1.进入系统模式2.切换IRF模式3.配置成员编号注:配置完成员编号后需要重启该设备。

4.配置成员优先级IRF2配置前应该将接口手工SHUT（没连线都不行）；12500系统默认都是SHUT的，95E以下必须手工SHUT5.配置IRF端口IRF2端口配置后应该将接口手工undo shutdown；然后关闭电源，连接IRF线缆，重启，IRF 形成。

6.使能BFD MAD检测注:此项与弟7项LACP MAD检测只能二选一，一般情况下使用BFD MAD检测。

7.使能LACP MAD检测8.配置保留端口9.手动恢复处于Recovery 状态的设备注:缺省状态下设备会自动恢复，只有Master设备产生故障且无法自动恢复时才进行手动恢复，正常配置中无须配置此项。

10.重定向到指定的Slave 设备注:此命令用于配置备用主控板，如: “<系统名-Slave#成员编号/槽位号>”，例如“<Sysname-Slave#1/0>”，正常配置中无须配置此项。

11.IRF 显示和维护12.配置举例一．IRF典型配置举例（BFD MAD检测方式）1. 组网需求由于网络规模迅速扩大，当前中心交换机（Device A）转发能力已经不能满足需求，现需要在保护现有投资的基础上将网络转发能力提高一倍，并要求网络易管理、易维护。

2. 组网图图1-1IRF典型配置组网图（BFD MAD检测方式）3. 配置思路为了减少IRF形成过程中系统重启的次数，可以在独立运行模式下预配置IRF端口、成员编号、以及成员优先级，配置保存后切换运行模式到IRF模式，可直接与其它设备形成IRF。

典型配置举例一IRF检测方式）1.1.1 IRF典型配置举例（LACP MAD 1. 组网需求现的接入需求。

由于公司人员激增，接入层交换机提供的端口数目已经不能满足PC 需要在保护现有投资的基础上扩展端口接入数量，并要求网络易管理、易维护。

组网图2.典型配置组网图（LACP MAD1-13 IRF检测方式）图3. 配置思路Device A提供的接入端口数目已经不能满足网络需求，需要另外增加一台设备?Device B。

（本文以两台设备组成IRF为例，在实际组网中可以根据需要，将多台设备组成IRF，配置思路和配置步骤与本例类似）鉴于第二代智能弹性架构IRF技术具有管理简便、网络扩展能力强、可靠性高等?优点，所以本例使用IRF技术构建接入层（即在Device A和Device B上配置IRF功能）。

为了防止万一IRF链路故障导致IRF分裂、网络中存在两个配置冲突的IRF，需?要启用MAD 检测功能。

因为接入层设备较多，我们采用LACP MAD检测。

4. 配置步骤为便于区分，下文配置中假设IRF形成前Device A的系统名称为DeviceA，Device B的系统名称为Device B；中间设备Device C的系统名称为DeviceC。

(1)配置设备编号# Device A保留缺省编号为1，不需要进行配置。

2上将设备的成员编号修改为Device B在#<DeviceB> system-view[DeviceB] irf member 1 renumber 2Warning: Renumbering the switch number may result in configuration change or loss. Continue? [Y/N]:y [DeviceB](2)将两台设备断电后，按图1-13所示连接IRF链路，然后将两台设备上电。

# 在Device A上创建设备的IRF端口2，与物理端口Ten-GigabitEthernet1/0/25绑定，并保存配置。

一IRF典型配置举例1.1.1IRF典型配置举例（LACP MAD检测方式）1.组网需求由于公司人员激增，接入层交换机提供的端口数目已经不能满足PC的接入需求。

现需要在保护现有投资的基础上扩展端口接入数量，并要求网络易管理、易维护。

2.组网图图1-13 IRF典型配置组网图（LACP MAD 检测方式）3.配置思路Device A提供的接入端口数目已经不能满足网络需求，需要另外增加一台设备Device B。

（本文以两台设备组成IRF为例，在实际组网中可以根据需要，将多台设备组成IRF，配置思路和配置步骤与本例类似）鉴于第二代智能弹性架构IRF技术具有管理简便、网络扩展能力强、可靠性高等优点，所以本例使用IRF技术构建接入层（即在Device A和Device B上配置IRF 功能）。

为了防止万一IRF链路故障导致IRF分裂、网络中存在两个配置冲突的IRF，需要启用MAD检测功能。

因为接入层设备较多，我们采用LACP MAD检测。

4.配置步骤老说明为便于区分，下文配置中假设IRF形成前Device A的系统名称为DeviceA ，Device B的系统名称为Device B ;中间设备Device C的系统名称为DeviceC。

（1）配置设备编号# Device A 保留缺省编号为1，不需要进行配置。

#在Device B上将设备的成员编号修改为2。

<DeviceB> system-view[DeviceB] irf member 1 renumber 2Warning: Renumbering the switch number may result in configuration change or loss.Continue? [Y/N]:y[DeviceB](2)将两台设备断电后，按图1-13所示连接IRF链路，然后将两台设备上电。

#在Device A 上创建设备的IRF 端口2,与物理端口Ten-GigabitEthernet1/0/25 绑定，并保存配置。

H3C IRF原理及配置1、概述IRF（Intelligent Resilient Framework，智能弹性架构）是H3C自主研发的软件虚拟化技术。

它的核心思想是将多台设备通过IRF物理端口连接在一起，进行必要的配置后，虚拟化成一台“分布式设备”。

理解为堆叠有助于我们更快理解2、工作原理IRF分为四阶段：物理连接、设备间通过IRF端口进行信息收集、选举主备关系、IRF自行维护。

只需了解选举规则以及分裂处理机制，其它信息不必深入。

如果有需要可以单独debugIRF信息即可。

选举规则：根据IRF的优先级进行选举，Priority值大的则为MASTER，值小的为SLAVE。

分裂机制： (1)IRF分裂分为两种情况，主机或者备机整机down掉，那么OK直接更换新设备即可。

(2)如果是IRF链路或者端口down掉，主备之间需要IRF的心跳线（MAD 检测）彼此互换IRF信息. 为避免二层信息混乱，IRF是让备机完全处于停机状态，It really doesnt work .3、常用名词IRF合并、IRF分裂、IRF端口、IRF角色、IRF主备4、IRF配置示例（1）配置A机为MASTER#设成员号及优先级irf mem 1 pri 4#把需要加入irf-port的端口down掉，shutdown XGE1/2/1,XGE1/2/2。

并加入相应的IRF group组interface Ten-GigabitEthernet1/2/1shutinterface Ten-GigabitEthernet1/2/2shutirf-port 1/1des IRF_PORT_1port group interface Ten-GigabitEthernet1/2/1port group interface Ten-GigabitEthernet1/2/2#重要一步，激活IRF，很多人会忽略这条命令。

irf-port configuration active#保存配置save（2）配置B机为SLAVE#设成员号及优先级,H3C设备默认都是mem 1，需要retu为mem 2。

目录1 IRF典型配置举例 ······························································································································· 1-11.1 简介 ··················································································································································· 1-11.2 使用限制············································································································································ 1-11.2.1 硬件限制 ································································································································· 1-11.2.2 软件限制 ································································································································· 1-11.2.3 单板使用限制 ·························································································································· 1-11.2.4 IRF端口连接限制 ···················································································································· 1-11.3 选择MAD检测方式····························································································································· 1-21.4 使用四台设备搭建IRF典型配置举例（LACP MAD检测方式） ························································· 1-21.4.1 适用产品和版本 ······················································································································ 1-21.4.2 组网需求 ································································································································· 1-21.4.3 搭建IRF的配置························································································································ 1-31.4.4 LACP MAD配置 ······················································································································ 1-81.4.5 业务配置 ······························································································································· 1-101.4.6 验证配置 ······························································································································· 1-141.4.7 配置文件 ······························································································································· 1-161.5 使用四台设备搭建IRF典型配置举例（BFD MAD检测方式）·························································· 1-211.5.1 适用产品和版本 ···················································································································· 1-211.5.2 组网需求 ······························································································································· 1-211.5.3 搭建IRF的配置······················································································································ 1-221.5.4 BFD MAD配置 ······················································································································ 1-261.5.5 业务配置 ······························································································································· 1-281.5.6 验证配置 ······························································································································· 1-331.5.7 配置文件 ······························································································································· 1-351 IRF典型配置举例本手册中的举例仅适用于S10500系列交换机。

一IRF典型配置举例1.1.1 IRF典型配置举例（LACP MAD检测方式）1. 组网需求由于公司人员激增，接入层交换机提供的端口数目已经不能满足PC的接入需求。

现需要在保护现有投资的基础上扩展端口接入数量，并要求网络易管理、易维护。

2. 组网图图1-13 IRF典型配置组网图（LACP MAD检测方式）3. 配置思路●Device A提供的接入端口数目已经不能满足网络需求，需要另外增加一台设备Device B。

（本文以两台设备组成IRF为例，在实际组网中可以根据需要，将多台设备组成IRF，配置思路和配置步骤与本例类似）●鉴于第二代智能弹性架构IRF技术具有管理简便、网络扩展能力强、可靠性高等优点，所以本例使用IRF技术构建接入层（即在Device A和Device B上配置IRF功能）。

●为了防止万一IRF链路故障导致IRF分裂、网络中存在两个配置冲突的IRF，需要启用MAD检测功能。

因为接入层设备较多，我们采用LACP MAD检测。

4. 配置步骤为便于区分，下文配置中假设IRF形成前Device A的系统名称为DeviceA，Device B的系统名称为Device B；中间设备Device C的系统名称为DeviceC。

(1)配置设备编号# Device A保留缺省编号为1，不需要进行配置。

# 在Device B上将设备的成员编号修改为2。

<DeviceB> system-view[DeviceB] irf member 1 renumber 2Warning: Renumbering the switch number may result in configuration change or loss. Continue? [Y/N]:y[DeviceB](2)将两台设备断电后，按图1-13所示连接IRF链路，然后将两台设备上电。

# 在Device A上创建设备的IRF端口2，与物理端口Ten-GigabitEthernet1/0/25绑定，并保存配置。

目录1 IRF配置.............................................................................................................................................. 1-11.1 IRF简介 ............................................................................................................................................. 1-11.1.1 IRF概述................................................................................................................................... 1-11.1.2 IRF的优点 ............................................................................................................................... 1-11.1.3 IRF的应用 ............................................................................................................................... 1-11.2 IRF基本概念 ...................................................................................................................................... 1-21.3 IRF工作原理 ...................................................................................................................................... 1-31.3.1 物理连接 ................................................................................................................................. 1-31.3.2 拓扑收集 ................................................................................................................................. 1-61.3.3 角色选举 ................................................................................................................................. 1-61.3.4 IRF的管理与维护 .................................................................................................................... 1-71.3.5 多IRF冲突检测（MAD功能） ................................................................................................. 1-91.4 IRF配置任务简介............................................................................................................................. 1-101.5 IRF配置 ........................................................................................................................................... 1-111.5.1 配置IRF域编号...................................................................................................................... 1-111.5.2 配置成员编号 ........................................................................................................................ 1-131.5.3 配置IRF端口 ......................................................................................................................... 1-141.5.4 配置成员优先级 .................................................................................................................... 1-151.5.5 配置成员设备的描述信息...................................................................................................... 1-151.5.6 配置IRF链路的负载分担类型 ................................................................................................ 1-161.5.7 配置IRF的桥MAC保留时间................................................................................................... 1-171.5.8 使能IRF系统启动文件的自动加载功能.................................................................................. 1-181.5.9 配置IRF链路down延迟上报功能 ........................................................................................... 1-191.6 MAD配置 ......................................................................................................................................... 1-201.6.1 LACP MAD检测 .................................................................................................................... 1-201.6.2 BFD MAD检测 ...................................................................................................................... 1-221.6.3 ARP MAD检测 ...................................................................................................................... 1-241.6.4 配置保留接口 ........................................................................................................................ 1-261.6.5 MAD故障恢复 ....................................................................................................................... 1-261.7 访问IRF ........................................................................................................................................... 1-281.7.1 访问Master ........................................................................................................................... 1-281.7.2 访问Slave ............................................................................................................................. 1-281.8 IRF显示和维护 ................................................................................................................................ 1-291.9 IRF典型配置举例............................................................................................................................. 1-301.9.1 IRF典型配置举例（LACP MAD检测方式）.......................................................................... 1-30 1.9.2 IRF典型配置举例（BFD MAD检测方式） ............................................................................ 1-32 1.9.3 IRF典型配置举例（ARP MAD检测方式） ............................................................................ 1-351 IRF配置S5800系列和S5820X系列交换机不但可以与本系列内的设备建立IRF，而且这两个系列的设备之间也能够建立IRF。

H3C-IRF配置指导------ 据H3C官方技术文档整理yang 2012.2.231.1 IRF简介IRF（Intelligent Resilient Framework，智能弹性架构）是H3C自主研发的软件虚拟化技术，它的核心思想是将多台设备通过IRF物理端口连接在一起，进行必要的配置后，虚拟化成一台“虚拟设备”。

使用这种虚拟化技术可以集合多台设备的硬件资源和软件处理能力，实现多台设备的协同工作、统一管理和不间断维护。

1.1.2 IRF的优点1、简化管理。

IRF形成之后，用户连接到任何一台成员设备的任何一个端口都可以登录IRF系统，对IRF内所有成员设备进行统一配置和统一管理。

2、强大的网络扩展能力。

通过增加成员设备，可以轻松自如的扩展IRF系统的端口数、带宽和处理能力。

3、高可靠性。

IRF的高可靠性体现在多个方面，比如：IRF由两台成员设备组成，Master 设备负责IRF的运行、管理和维护，Slave设备在作为备份的同时也可以处理业务。

一旦Master设备故障，系统会迅速自动选举新的Master，以保证通过IRF的业务不中断，从而实现了设备的1:N备份；成员设备之间IRF物理端口支持聚合功能，IRF和上、下层设备之间的物理连接也支持聚合功能，这样通过多链路备份提高了IRF系统的可靠性。

1.2 基本概念1. 角色IRF中所有的单台设备称为成员设备。

成员设备按照功能不同，分为两种角色：Master：负责管理整个IRF的成员设备，由角色选举产生。

一个IRF中同一时刻只能有一台Master设备。

Slave：隶属于Master设备的成员设备，作为Master设备的备份设备运行，由角色选举产生。

IRF中除了Master设备，其它设备都是Slave设备。

2. 成员编号IRF中使用成员编号（Member ID）来标识和管理成员设备，IRF中所有设备的成员编号都是唯一的。

比如，IRF中接口的编号会加入成员编号信息：设备在独立运行模式下，某个接口的编号为GigabitEthernet3/0/1；当该设备加入IRF后，如果成员编号为2，则该接口的编号将变为GigabitEthernet2/3/0/1。