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| Sumber: https://www.techrepublic.com/article/how-to-configure-basic-ospf/ | | Sumber: https://www.techrepublic.com/article/how-to-configure-basic-ospf/ |
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| To configure basic OSPF to form a neighbor adjacency on a Cisco router perform the following: | | To configure basic OSPF to form a neighbor adjacency on a Cisco router perform the following: |
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− | Identify the network interfaces that should run OSPF.
| + | * Identify the network interfaces that should run OSPF. |
− | Identify the OSPF area
| + | * Identify the OSPF area |
− | Issue the required commands to enable OSPF
| + | * Issue the required commands to enable OSPF |
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| Let's assume the following topology in which we are using OSPF area 5 and ABR5 and R5 are pre-configured for us. We need to enable OSPF on R6. | | Let's assume the following topology in which we are using OSPF area 5 and ABR5 and R5 are pre-configured for us. We need to enable OSPF on R6. |
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| Image: Brandon Carroll/TechRepublic | | Image: Brandon Carroll/TechRepublic |
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− | Start by entering OSPF configuration mode. You'll need to identify OSPF by a process ID. In this case, it's 1. | + | Start OSPF dengan meng-identifikasi router ospd (contoh 1): |
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− | R6>en | + | enable |
− | R6#conf t | + | configure terminal |
− | Enter configuration commands, one per line. End with CNTL/Z. | + | router ospf 1 |
− | R6(config)#router ospf 1
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− | R6(config-router)#
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− | Next, issue the network statement for each interface that should run OSPF. According to our network topology we will enable OSPF on interface g0/1 and g0/2. The network statement format is as follows:
| + | Jalankan network untuk Interface yang menjalankan OSPF, menggunakan format berikut |
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| network X.X.X.X W.W.W.W area A | | network X.X.X.X W.W.W.W area A |
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− | In this syntax, the X.X.X.X indicates the network address. The W.W.W.W is the wildcard mask. The A is the area ID.
| + | Dimana: |
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− | R6(config-router)#network 10.0.0.80 0.0.0.3 area 5
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− | R6(config-router)#network 10.0.0.84 0.0.0.3 area 5
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− | R6(config-router)#
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− | | |
− | A simple way to identify the wildcard mask is to subtract the subnet mask in the last octet from 255. In this case 255 - 252 - 3 so our wildcard mask is going to end in .3.
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− | | |
− | We now need to verify that OSPF has neighbored up and synchronized databases. To do so, issue the show ip ospf neighbors command.
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− | R6#sh ip ospf neighbor
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− | `
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− | Neighbor ID Pri State Dead Time Address Interface`
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− | 192.168.0.10 1 FULL/DR 00:00:35 10.0.0.85 GigabitEthernet0/2`
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− | 192.168.0.9 1 FULL/BDR 00:00:31 10.0.0.81 GigabitEthernet0/1`
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− | R6#`
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− | As we can tell from the output, we have two neighbors. The Neighbor ID is not the IP address that we neighbored with. It's the Router ID selected by OSPF when the protocol was enabled. This can be chosen automatically or you can manually set this value.
| + | * X.X.X.X - network address |
| + | * W.W.W.W - wildcard mask |
| + | * A - area ID. |
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− | Next let's look at our Link-State Database on R6.
| + | Contoh: |
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− | R6#show ip ospf database | + | network 10.0.0.80 0.0.0.3 area 5 |
| + | network 10.0.0.84 0.0.0.3 area 5 |
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− | OSPF Router with ID (10.0.0.86) (Process ID 1)
| + | W.W.W.W dihitung dari |
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− | Router Link States (Area 5)
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− | Link ID ADV Router Age Seq# Checksum Link count
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− | 10.0.0.86 10.0.0.86 164 0x80000003 0x00EFF7 2
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− | 192.168.0.9 192.168.0.9 165 0x80000006 0x00A12F 2
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− | 192.168.0.10 192.168.0.10 229 0x80000006 0x00CC76 3
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− |
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− | Net Link States (Area 5)
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− |
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− | Link ID ADV Router Age Seq# Checksum
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− | 10.0.0.78 192.168.0.10 1598 0x80000004 0x004B3D
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− | 10.0.0.82 10.0.0.86 164 0x80000001 0x00C7E5
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− | 10.0.0.85 192.168.0.10 229 0x80000001 0x008313
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− |
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− | Summary Net Link States (Area 5)
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− |
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− | Link ID ADV Router Age Seq# Checksum
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− | 10.0.0.4 192.168.0.9 1630 0x80000004 0x00A217
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− | 10.0.0.8 192.168.0.9 1630 0x80000004 0x007046
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− | 10.0.0.12 192.168.0.9 1630 0x80000004 0x00486A
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− | 10.0.0.16 192.168.0.9 1630 0x80000004 0x00208E
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− | 10.0.0.20 192.168.0.9 1630 0x80000004 0x00F7B2
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− | 10.0.0.24 192.168.0.9 1630 0x80000004 0x00C5E1
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− | 10.0.0.28 192.168.0.9 1630 0x80000004 0x00A7FA
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− | 10.0.0.32 192.168.0.9 1630 0x80000004 0x007F1F
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− | 10.0.0.36 192.168.0.9 1630 0x80000004 0x005743
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− | 10.0.0.40 192.168.0.9 1630 0x80000004 0x002572
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− | 10.0.0.44 192.168.0.9 1630 0x80000004 0x00078B
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− | 10.0.0.48 192.168.0.9 1630 0x80000004 0x00DEAF
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− | 10.0.0.52 192.168.0.9 1630 0x80000005 0x00B4D4
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− | 10.0.0.56 192.168.0.9 1630 0x80000004 0x008EF7
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− | 10.0.0.60 192.168.0.9 1630 0x80000004 0x007011
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− | 10.0.0.64 192.168.0.9 1630 0x80000004 0x00344B
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− | 10.0.0.68 192.168.0.9 1630 0x80000005 0x001465
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− | 10.0.0.72 192.168.0.9 1630 0x80000004 0x00E393
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− | 192.168.0.1 192.168.0.9 1630 0x80000004 0x0099C1
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− | 192.168.0.2 192.168.0.9 1630 0x80000004 0x0099BF
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− | 192.168.0.3 192.168.0.9 1630 0x80000004 0x008FC8
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− | 192.168.0.4 192.168.0.9 1630 0x80000004 0x007BDC
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− | 192.168.0.5 192.168.0.9 1630 0x80000004 0x0071E5
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− | 192.168.0.6 192.168.0.9 1630 0x80000004 0x0071E3
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− | 192.168.0.8 192.168.0.9 1630 0x80000005 0x005102
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− | 192.168.0.9 192.168.0.9 1630 0x80000004 0x003F15
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− | R6#
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− | Comparing database with R5, specifically the sequence numbers, we can see that we are synchronized:
| + | 255.255.255.255 - 255.255.255.252 = 0.0.0.3 |
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− | R5#sh ip ospf database
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− |
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− | OSPF Router with ID (192.168.0.10) (Process ID 1)
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− |
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− | Router Link States (Area 5)
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− | Link ID ADV Router Age Seq# Checksum Link count
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− | 10.0.0.86 10.0.0.86 193 0x80000003 0x00EFF7 2
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− | 192.168.0.9 192.168.0.9 194 0x80000006 0x00A12F 2
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− | 192.168.0.10 192.168.0.10 257 0x80000006 0x00CC76 3
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− |
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− | Net Link States (Area 5)
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− | Link ID ADV Router Age Seq# Checksum
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− | 10.0.0.78 192.168.0.10 1626 0x80000004 0x004B3D
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− | 10.0.0.82 10.0.0.86 193 0x80000001 0x00C7E5
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− | 10.0.0.85 192.168.0.10 257 0x80000001 0x008313
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− |
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− | Summary Net Link States (Area 5)
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− | Link ID ADV Router Age Seq# Checksum
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− | 10.0.0.4 192.168.0.9 1658 0x80000004 0x00A217
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− | 10.0.0.8 192.168.0.9 1658 0x80000004 0x007046
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− | 10.0.0.12 192.168.0.9 1658 0x80000004 0x00486A
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− | 10.0.0.16 192.168.0.9 1658 0x80000004 0x00208E
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− | 10.0.0.20 192.168.0.9 1658 0x80000004 0x00F7B2
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− | 10.0.0.24 192.168.0.9 1658 0x80000004 0x00C5E1
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− | 10.0.0.28 192.168.0.9 1658 0x80000004 0x00A7FA
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− | 10.0.0.32 192.168.0.9 1658 0x80000004 0x007F1F
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− | 10.0.0.36 192.168.0.9 1658 0x80000004 0x005743
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− | 10.0.0.40 192.168.0.9 1658 0x80000004 0x002572
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− | 10.0.0.44 192.168.0.9 1658 0x80000004 0x00078B
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− | 10.0.0.48 192.168.0.9 1658 0x80000004 0x00DEAF
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− | 10.0.0.52 192.168.0.9 1658 0x80000005 0x00B4D4
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− | 10.0.0.56 192.168.0.9 1658 0x80000004 0x008EF7
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− | 10.0.0.60 192.168.0.9 1658 0x80000004 0x007011
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− | 10.0.0.64 192.168.0.9 1658 0x80000004 0x00344B
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− | 10.0.0.68 192.168.0.9 1658 0x80000005 0x001465
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− | 10.0.0.72 192.168.0.9 1658 0x80000004 0x00E393
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− | 192.168.0.1 192.168.0.9 1658 0x80000004 0x0099C1
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− | 192.168.0.2 192.168.0.9 1658 0x80000004 0x0099BF
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− | 192.168.0.3 192.168.0.9 1658 0x80000004 0x008FC8
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− | 192.168.0.4 192.168.0.9 1658 0x80000004 0x007BDC
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− | 192.168.0.5 192.168.0.9 1658 0x80000004 0x0071E5
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− | 192.168.0.6 192.168.0.9 1658 0x80000004 0x0071E3
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− | 192.168.0.8 192.168.0.9 1658 0x80000005 0x005102
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− | 192.168.0.9 192.168.0.9 1658 0x80000004 0x003F15
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− | Finally, let's look to see if we have OSPF routes populating our routing table on R6:
| + | Cek menggunakan neighbour & routing dengan perintah |
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− | R6#show ip route | + | show ip ospf neighbor |
− | Codes: L - local, C - connected, S - static, R - RIP, M - mobile, B - BGP | + | show ip ospf database |
− | D - EIGRP, EX - EIGRP external, O - OSPF, IA - OSPF inter area
| + | show ip route |
− | N1 - OSPF NSSA external type 1, N2 - OSPF NSSA external type 2
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− | E1 - OSPF external type 1, E2 - OSPF external type 2
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− | i - IS-IS, su - IS-IS summary, L1 - IS-IS level-1, L2 - IS-IS level-2
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− | ia - IS-IS inter area, * - candidate default, U - per-user static route
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− | o - ODR, P - periodic downloaded static route, H - NHRP, l - LISP
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− | a - application route
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− | replicated route, % - next hop override, p - overrides from PfR | |
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− | Gateway of last resort is not set
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− |
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− | 10.0.0.0/8 is variably subnetted, 23 subnets, 2 masks
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− | O IA 10.0.0.4/30 [110/4] via 10.0.0.81, 00:05:24, GigabitEthernet0/1
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− | O IA 10.0.0.8/30 [110/3] via 10.0.0.81, 00:05:24, GigabitEthernet0/1
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− | O IA 10.0.0.12/30 [110/3] via 10.0.0.81, 00:05:24, GigabitEthernet0/1
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− | O IA 10.0.0.16/30 [110/3] via 10.0.0.81, 00:05:24, GigabitEthernet0/1
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− | O IA 10.0.0.20/30 [110/3] via 10.0.0.81, 00:05:24, GigabitEthernet0/1
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− | O IA 10.0.0.24/30 [110/2] via 10.0.0.81, 00:05:24, GigabitEthernet0/1
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− | O IA 10.0.0.28/30 [110/3] via 10.0.0.81, 00:05:24, GigabitEthernet0/1
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− | O IA 10.0.0.32/30 [110/3] via 10.0.0.81, 00:05:24, GigabitEthernet0/1
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− | O IA 10.0.0.36/30 [110/3] via 10.0.0.81, 00:05:24, GigabitEthernet0/1
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− | O IA 10.0.0.40/30 [110/2] via 10.0.0.81, 00:05:24, GigabitEthernet0/1
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− | O IA 10.0.0.44/30 [110/3] via 10.0.0.81, 00:05:24, GigabitEthernet0/1
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− | O IA 10.0.0.48/30 [110/3] via 10.0.0.81, 00:05:24, GigabitEthernet0/1
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− | O IA 10.0.0.52/30 [110/3] via 10.0.0.81, 00:05:24, GigabitEthernet0/1
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− | O IA 10.0.0.56/30 [110/3] via 10.0.0.81, 00:05:24, GigabitEthernet0/1
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− | O IA 10.0.0.60/30 [110/4] via 10.0.0.81, 00:05:24, GigabitEthernet0/1
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− | O IA 10.0.0.64/30 [110/2] via 10.0.0.81, 00:05:24, GigabitEthernet0/1
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− | O IA 10.0.0.68/30 [110/3] via 10.0.0.81, 00:05:24, GigabitEthernet0/1
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− | O IA 10.0.0.72/30 [110/2] via 10.0.0.81, 00:05:24, GigabitEthernet0/1
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− | O 10.0.0.76/30 [110/2] via 10.0.0.85, 00:06:30, GigabitEthernet0/2
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− | [110/2] via 10.0.0.81, 00:05:24, GigabitEthernet0/1
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− | C 10.0.0.80/30 is directly connected, GigabitEthernet0/1
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− | L 10.0.0.82/32 is directly connected, GigabitEthernet0/1
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− | C 10.0.0.84/30 is directly connected, GigabitEthernet0/2
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− | L 10.0.0.86/32 is directly connected, GigabitEthernet0/2
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− | 192.168.0.0/32 is subnetted, 9 subnets
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− | O IA 192.168.0.1 [110/3] via 10.0.0.81, 00:05:24, GigabitEthernet0/1
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− | O IA 192.168.0.2 [110/4] via 10.0.0.81, 00:05:24, GigabitEthernet0/1
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− | O IA 192.168.0.3 [110/4] via 10.0.0.81, 00:05:24, GigabitEthernet0/1
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− | O IA 192.168.0.4 [110/3] via 10.0.0.81, 00:05:24, GigabitEthernet0/1
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− | O IA 192.168.0.5 [110/3] via 10.0.0.81, 00:05:24, GigabitEthernet0/1
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− | O IA 192.168.0.6 [110/4] via 10.0.0.81, 00:05:24, GigabitEthernet0/1
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− | O IA 192.168.0.8 [110/3] via 10.0.0.81, 00:05:24, GigabitEthernet0/1
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− | O IA 192.168.0.9 [110/2] via 10.0.0.81, 00:05:24, GigabitEthernet0/1
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− | O 192.168.0.10 [110/2] via 10.0.0.85, 00:06:30, GigabitEthernet0/2
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− | R6#
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− | As you can tell, we are receiving OSPF routes. In fact, we are receiving more routes to destinations that we don't see in our topology. This is because we are only focusing on a small part of the topology. What we don't see is that ABR5 is connected to several other routers forming a backbone and exchanging routes between other areas. This obviously leads to more questions about OSPF, however, as it stands we have configured basic OSPF and can now route traffic on R6.
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| ==Pranala Menarik== | | ==Pranala Menarik== |
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− | * [{Cisco]] | + | * [[Cisco]] |
Sumber: https://www.techrepublic.com/article/how-to-configure-basic-ospf/
Open shortest path first, or OSPF, is a routing protocol that's based on open standards, meaning any vendor can implement its features. For years Cisco, Juniper, and other major networking vendors have coupled OSPF into their platform. When you configure OSPF, there are a few fundamental requirements in order to exchange routing information. To begin with, OSPF uses a Hello mechanism to detect neighboring devices that run OSPF. Once detected OSPF attempts to form an adjacency. Once an adjacency is established Link-State Advertisements (LSA) are used to exchange routing information.
The Hello packet is one of the first things you should have a solid understanding of. The following image shows the format of a Hello packet:
1.jpg
Image: Brandon Carroll/TechRepublic
This packet is used by the Hello protocol, which is responsible for establishing and maintaining neighbor relationships. The Hello protocol also ensures that communication between neighbors is bidirectional. These packets get sent out of an interface where OSPF is enabled on a periodic basis. If a router receives a packet and sees its own address listed it knows that bidirectional communication exists. Once bidirectional communication is established a Designated Router (DR) is selected if on a multiaccess network. We're not going to cover that process in this article, however we highlight it because it's an integral part of OSPF. After two devices neighbor up, they synchronize Link-State databases.
SEE: 20 quick tips to make Linux networking easier
To configure basic OSPF to form a neighbor adjacency on a Cisco router perform the following:
- Identify the network interfaces that should run OSPF.
- Identify the OSPF area
- Issue the required commands to enable OSPF
Let's assume the following topology in which we are using OSPF area 5 and ABR5 and R5 are pre-configured for us. We need to enable OSPF on R6.
2.jpg
Image: Brandon Carroll/TechRepublic
Start OSPF dengan meng-identifikasi router ospd (contoh 1):
enable
configure terminal
router ospf 1
Jalankan network untuk Interface yang menjalankan OSPF, menggunakan format berikut
network X.X.X.X W.W.W.W area A
Dimana:
- X.X.X.X - network address
- W.W.W.W - wildcard mask
- A - area ID.
Contoh:
network 10.0.0.80 0.0.0.3 area 5
network 10.0.0.84 0.0.0.3 area 5
W.W.W.W dihitung dari
255.255.255.255 - 255.255.255.252 = 0.0.0.3
Cek menggunakan neighbour & routing dengan perintah
show ip ospf neighbor
show ip ospf database
show ip route
Referensi
Pranala Menarik