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CCIE Enterprise Infrastructure Exam Topics - Practical Exam. Y( y6 v. `/ x
Exam Description
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The Cisco CCIE Enterprise Infrastructure (v1.0) Practical Exam is an eight-hour, hands-on exam that requires a candidate to plan, design, deploy, operate, and optimize dual stack solutions (IPv4 and IPv6) for complex enterprise networks.. e, r/ {2 e) h/ \+ T
# B$ s5 U/ J: gCandidates are expected to program and automate the network within their exam, as per exam topics below.
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$ I6 M2 K, P5 f! xThe following topics are general guidelines for the content likely to be included on the exam. Your knowledge, skills and abilities on these topics will be tested throughout the entire network lifecycle, unless explicitly specified otherwise within this document./ L. w8 D3 I( x5 s
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第一部分 network infrastructure 30%
' f% W( E) |/ K! M7 T8 L1.1 Switched campus! g7 O, g. t F: V6 z8 R
1.1.a Switch administration
. U- {' B4 T. }1.1.a i Managing MAC address table h# r Z0 Z* `8 U& e6 B
1.1.a ii Errdisable recovery
8 Z" b9 p: R, V/ y, M* b: [( \( A1.1.a iii L2 MTU* J' ~" @' g8 U4 o* A* d* K2 ], L
1.1.b Layer 2 protocols9 G/ \% L% \1 x8 v2 \
1.1.b i CDP, LLDP
2 T* B& q* j5 K) Q4 \1.1.b ii UDLD
$ J1 H I& E5 M" F% j; W$ y+ M1.1.c VLAN technologies
/ b1 ^3 O" t, b w" \1.1.c i Access ports
6 N/ Z. g c/ ]5 i6 J( D1.1.c ii Trunk ports (802.1Q)
) `& L3 l) m0 a1 s1.1.c iii Native VLAN( H( r4 {4 x7 l) T2 W/ N
1.1.c iv Manual VLAN pruning; `7 o' m& j" S3 O1 v5 C
1.1.c v VLAN database5 B5 g7 f, O& J6 D7 X+ w3 P
1.1.c vi Normal range and extended range VLANs$ Y/ P1 s# _# [* ^' X+ J, X) l
1.1.c vii Voice VLAN
/ A! f+ }8 i8 u1.1.c viii VTP
3 G9 v: R9 f4 r1.1.d EtherChannel
) y* e+ A6 A/ B3 W" p1.1.d i LACP, static9 N& c" v& R6 s9 S4 {* X6 x) P
1.1.d ii Layer 2, Layer 35 O$ z4 t/ A- N! l* z/ Q" D2 k! d
1.1.d iii Load balancing$ A/ w6 d+ O8 l5 A6 m
1.1.d iv EtherChannel Misconfiguration Guard
* r* G, E2 m, r& @! _0 ~) _- o1.1.e Spanning- Tree Protocol
" l- t! W T& K) h0 F* m4 o/ x5 [, p1.1.e i PVST+, Rapid PVST+, MST" b/ _7 ]3 \: k9 x5 v- {" v
1.1.e ii Switch priority, port priority, path cost, STP timers
' Z r5 a( h. F8 a1.1.e iii PortFast, BPDU Guard, BPDU Filter
2 ]& a4 k; b& K# D6 @1.1.e iv Loop Guard, Root Guard5 ~% N: b3 x$ j7 q6 @
1.2 Routing Concepts
1 B& B2 f, H. K" B4 x6 m. x& R1.2.a Administrative distance
" W& V V0 j* E) ^( Z- B1 k1.2.b VRF-lite; O# C: {) H) P9 R
1.2.c Static routing
, z. L1 M% S4 V% o5 t2 R1.2.d Policy Based Routing( x1 P# E# E" ~- V {
1.2.e VRF aware routing with any routing protocol; B3 g! v9 P- q+ x
1.2.f Route filtering with any routing protocol' N8 M2 h+ X6 p; W# w) j, P
1.2.g Manual summarization with any routing protocol
% E" K) G2 }/ A; e( n1.2.h Redistribution between any pair of routing protocols
3 [! U* g$ Y- p$ S7 }' R8 T. d* s1.2.i Routing protocol authentication
T- k+ ?4 t7 k0 a1.2.j Bidirectional Forwarding Detection
5 Y" ^& B/ y% r) i" l: K1 W$ N1.3 EIGRP, k: }( z* J; B5 p7 z
1.3.a Adjacencies
, i' y/ h; j1 d7 v1.3.b Best path selection
6 S7 d0 ?) C) s" P" Z1.3.b i RD, FD, FC, successor, feasible successor% T. Z8 X8 U8 y) h. e: C k, E# W
1.3.b ii Classic Metrics and Wide Metrics' h, i- o% ?# I+ q
1.3.c Operations7 W9 `, ?# |; k4 g D P* B! H
1.3.c i General operations" Q/ b) p& Q' k% C
1.3.c ii Topology table
8 ^4 d- b2 _. h1 @4 i9 n3 c4 m1.3.c iii Packet types) ~' d2 N; t( t$ ]- ]
1.3.c iv Stuck In Active& [3 l1 Y8 |! Z' `
1.3.c v Graceful shutdown
9 ^4 w3 @- r0 X4 H: E. m; f1.3.d EIGRP load-balancing$ Y- Y; R/ e! ], a
1.3.d i Equal-cost! N" \) O8 z& F8 L' |3 a
1.3.d ii Unequal-cost5 r/ c- w6 W5 B8 |
1.3.d iii Add-path
5 B& ^: T* K: G3 M; }1.3.e EIGRP Named Mode
0 N: ~* K! @/ _- [9 a4 p$ f8 k1.3.f Optimization, convergence and scalability
) y5 }0 u I# [1.3.f i Fast convergence requirements, ~0 E0 L4 A4 c6 J K- M' C
1.3.f ii Query propagation boundaries% l, k8 c0 k+ s: D. E5 u- t
1.3.f iii IP FRR (single hop) f5 I% e! T9 ~0 c8 R
1.3.f iv Leak-map with summary routes i5 Y' D$ J) H+ \' Z7 R
1.3.f v EIGRP stub with leak map
5 ` Y# f# p6 A4 Q1.4 OSPF (v2 and v3)! W1 `7 k" ~+ z, F0 a7 T
1.4.a Adjacencies
+ t3 c1 N1 p1 l+ v" d& b7 ^1.4.b Network types, area types
! S+ \7 |* }2 R* z1.4.c Path preference$ w; H5 }2 d5 S( Q. p$ J+ V
1.4.d Operations
) y1 f0 ]5 h* y; x1.4.d i General operations
" l) a2 [+ ?8 u) U: ~* U9 p; |1.4.d ii Graceful shutdown
$ }0 m, w5 J3 n9 i2 @. d* n# |1.4.d iii GTSM (Generic TTL Security Mechanism)
6 _7 ^! S5 N1 r6 W& l9 f% h5 N4 L1.4.e Optimization, convergence and scalability H: m9 b3 ~) w/ ?% Z e
1.4.e i Metrics
3 [0 N9 b6 t4 Z4 d: A' G1.4.e ii LSA throttling, SPF tuning, fast hello* m" p; q" [! j. a
1.4.e iii LSA propagation control (area types)
9 T: P! w# z+ @& S4 y1.4.e iv Stub router9 L' T! Q- ~* Z: G' ?
1.4.e v Loop-free alternate& c T6 C1 q! Q$ u3 w
1.4.e vi Prefix suppression
7 ^ o/ W V% B7 l) F. e. d& v1.5 BGP7 v& R. X' i( n% i
1.5.a IBGP and EBGP peer relationships X& v2 p* m6 m X
1.5.a i Peer-group/update-group, template
2 E& g' A1 @$ n1.5.a ii Active, passive
/ K. d0 r6 \0 m1.5.a iii Timers2 r, K* l" C% I/ L* ~
1.5.a iv Dynamic neighbors& r: |: W+ X9 G
1.5.a v 4-bytes AS numbers5 [" `$ n3 K+ K% t
1.5.a vi Private AS
& a6 A' U i2 w, I! _ z+ `! x1.5.b Path selection
7 G9 W/ l' A4 J( H, C9 X1.5.b i Attributes5 m5 ]& G9 {; \% O D; c4 ^3 ]' M5 S
1.5.b ii Best path selection algorithm Q* s. _/ t' Z: l {
1.5.b iii Load-balancing X' l6 k9 H2 p' L: O
1.5.c Routing policies- }+ T4 b; k% D8 M# B
1.5.c i Attribute manipulation
) P3 Q- }' R) I2 _ b1.5.c ii Conditional advertisement5 \# S+ L$ ]6 r4 `7 F, `
1.5.c iii Outbound Route Filtering* V0 q3 I" Q0 ], t( g
1.5.c iv Standard and extended communities# z) _& I c3 M% H- a" }$ X
1.5.c v Multi-homing2 E! R v) r( A, t/ H; b
1.5.d AS path manipulations J! \, a! F1 |# I
1.5.d i local-AS, allowas-in, remove-private-as
) ?' q1 |4 f. i; Q5 a2 Y8 J8 ~1.5.d ii Prepend
; Z( v& C0 S5 s, {2 h1.5.d iii Regexp
8 n% H7 n6 p3 d6 K" h) |# t6 G1.5.e Convergence and scalability, p+ J, s4 Q/ B; U' o" F8 g
1.5.e i Route reflector9 }8 i2 `7 ~% Y/ k2 x& H# L
1.5.e ii Aggregation, as-set
8 V; Q. R' L ^* u9 j1 Z1.5.f Other BGP features! g4 d4 u: k$ R% }6 `; X# u
1.5.f i Multipath, add-path
' L7 w# z( o1 p1.5.f ii Soft reconfiguration, Route Refresh
4 z2 A! }. e/ j% O" L1 h1.6 Multicast( w& X" [# S0 o$ J2 }9 g, O# B1 q* R% j
1.6.a Layer 2 multicast
3 b6 x2 p9 _' _1.6.a i IGMPv2, IGMPv3
0 r3 |( p3 A& y: z: l. F9 p4 s1.6.a ii IGMP Snooping, PIM Snooping
8 f2 V9 [3 z" U U9 [5 T) [1.6.a iii IGMP Querier
4 F4 m. m% s/ e/ J' P1.6.a iv IGMP Filter# W/ N% y! E- z/ b: V
1.6.a v MLD
* M1 {/ Y9 B0 S0 w, [* B8 u1.6.b Reverse path forwarding check! C' g% H: M" ]( E6 @! ^. h( J7 ~
1.6.c PIM
3 ?& Y. Y6 C! q+ R* x1.6.c i Sparse Mode+ Q! I: ?2 ^% o% @3 T* F1 R' ~8 ]
1.6.c ii Static RP, BSR, AutoRP
; Y- R) z( V/ B( s' |7 n1.6.c iii Group to RP Mapping
' H( R9 [0 J; o' K C* m! E$ {1.6.c iv Bidirectional PIM
% R8 f( i$ G5 a# S8 g1.6.c v Source-Specific Multicast
5 J0 F0 j, n1 N s- k6 ?8 K1.6.c vi Multicast boundary, RP announcement filter
$ w* i. E6 D- U3 }1.6.c vii PIMv6 Anycast RP
, w5 ?/ J% ?3 g9 b, ~! q4 {/ Q1.6.c viii IPv4 Anycast RP using MSDP1 L! j8 X+ q1 J' ?7 d
1.6.c ix Multicast multipath& |2 N# W0 \( T" x
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第二部分 software defined infrastructure 25%
& m4 N# {) u% i e, }( P: P2.1 Cisco SD Access& t( J/ b' s5 N1 C3 Z
2.1.a Design a Cisco SD Access solution
" g/ p' ^$ z' F/ J [0 x0 i, t2.1.a i Underlay network (IS-IS, manual/PnP)
- x$ j! b' K0 l4 g3 C9 O* h2.1.a ii Overlay fabric design (LISP, VXLAN, Cisco TrustSec)
9 v2 C: U8 J/ _5 a' h2.1.a iii Fabric domains (single-site and multi-site using SD-WAN transit)& s) G) x% N$ e9 z( T$ p! Z0 t
2.1.b Cisco SD Access deployment5 p" [/ E) g. @) t# X6 [7 F2 T
2.1.b i Cisco DNA Center device discovery and device management1 h0 R- Y, H/ Q6 w
2.1.b ii Add fabric node devices to an existing fabric: Y% Q& [/ A2 w) f# b+ p8 x% I+ n
2.1.b iii Host onboarding (wired endpoints only)
2 {4 s. T) |) j' U" `8 T2.1.b iv Fabric border handoff2 ] Y" g/ G2 _
2.1.c Segmentation$ H. R- m. B( \. J' v0 I
2.1.c i Macro-level segmentation using VNs
/ _( |% ?8 I- H6 e2.1.c ii Micro-level segmentation using SGTs (using Cisco ISE)
4 u Y: m9 g& N2 l2.1.d Assurance
1 J( _( i1 P7 \0 L' J+ \2.1.d i Network and client health (360) B7 @. W& Q0 C6 M
2.1.d ii Monitoring and troubleshooting/ ] Q; w$ W$ _: }9 C
2.2 Cisco SD-WAN( D; w0 M2 q7 @ T2 j
2.2.a Design a Cisco SD-WAN solution- i6 V Z% q5 C
2.2.a i Orchestration plane (vBond, NAT)% {. a. a! @$ w. E/ x7 ?
2.2.a ii Management plane (vManage)
; C* n( y2 }# ?! m2 L2.2.a iii Control plane (vSmart, OMP)
; ` `. x V l8 r1 t2.2.a iv Data plane (vEdge/cEdge)9 c s! j: @* c6 y( c0 J
2.2.b WAN edge deployment1 M/ H: @8 t4 K# w; t7 n0 k
2.2.b i Onboarding new edge routers
4 f. }3 }9 _3 J5 I+ z2.2.b ii Orchestration with zero-touch provisioning/Plug-And-Play
Q- I" }/ _2 W' h) n! c3 @2.2.b iii OMP2 ^/ l8 }3 K% }6 O j
2.2.b iv TLOC
3 f) T" T8 ?( ~% d0 t: U2.2.c Configuration templates0 p. A7 {9 b' P# k: a# h
2.2.d Localized policies (only QoS)% y5 d6 A6 [: I' m0 i
2.2.e Centralized policies
9 A+ j1 t- v% I2.2.e i Application Aware Routing
. I1 K2 ~: x+ C: S7 N+ Q2.2.e ii Topologies2 I( G/ ?) E" Q: V: V
5 W' D- n4 R. D5 R8 z& B: D
第三部分 transport technologies and solutions 15%
9 v. ~' @: m0 ^3.1 MPLS
) }) K8 v- l3 s9 H7 G, ?, @: \" w# r3.1.a Operations
. m7 M* ~! Y1 B) ~: P3.1.a i Label stack, LSR, LSP
% _ f( P; H6 t$ K2 U7 ], t3.1.a ii LDP$ s- G3 H' B$ I9 b/ e# h9 k2 v
3.1.a iii MPLS ping, MPLS traceroute! F0 C" s5 e4 i& }2 Q# M
3.1.b L3VPN% e# T6 C# Q/ k5 D) G
3.1.b i PE-CE routing6 b) K X* V7 i
3.1.b ii MP-BGP VPNv4/VPNv6
) ], p7 z i; s3.1.b iii Extranet (route leaking)( X) [9 D5 f4 T8 n' l0 |, i j8 o
3.2 DMVPN3 B) B( C' G( y
3.2.a Troubleshoot DMVPN Phase 3 with dual-hub
' ]3 g! h$ O6 A7 b3.2.a i NHRP1 e- b1 ]' F9 _/ N8 X5 \1 g
3.2.a ii IPsec/IKEv2 using pre-shared key
& [" n8 {0 d& N& j3.2.a iii Per-Tunnel QoS
2 i, y( L# x$ `% @4 ~( z% ?3.2.b Identify use-cases for FlexVPN
( J2 c9 i2 A$ D3.2.b i Site-to-site, Server, Client, Spoke-to-Spoke
* Z4 m$ p4 p6 C! N2 i% R* }. ~3.2.b ii IPsec/IKEv2 using pre-shared key; ?; l/ W) d$ V! j. g0 O
3.2.b iii MPLS over FlexVPN! |5 m) g4 ?6 w/ L: t7 H2 s- ~
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第四部分 infrastructrue security and sevices 15%
/ k1 a9 u0 s+ ~( d }5 n) [1 N4.1 Device Security on Cisco IOS XE9 G1 s/ A! T2 c
4.1.a Control plane policing and p rotection
$ J* p8 ]2 [/ u" B- t7 n; E4.1.b AAA1 j1 k8 ^$ }* d: @ T" i( C
4.2 Network Security
% p1 t% d- E: L. N, k# V- u2 K4 i4.2.a Switch security features* `( a. {9 \" A' l4 {
4.2.a i VACL, PACL2 q2 ]5 L! r+ v5 P l% |% [3 r$ [
4.2.a ii Storm control, q1 s* B- [% t- J
4.2.a iii DHCP Snooping, DHCP option 820 n; _4 u/ t6 E2 k$ m# \7 K; O6 X
4.2.a iv IP Source Guard
: S/ i [- P, Y' }" e+ i s8 x4.2.a v Dynamic ARP Inspection0 T2 y$ g' p0 W9 |
4.2.a vi Port Security
; R1 H9 Q9 L0 @5 `3 x4.2.a vii Private VLAN6 O# J" d' I2 ^$ C
4.2.b Router security features
% g* I/ |) C, C& t- t8 g: T4.2.b i IPv6 Traffic Filters; r: H, Y- H6 _! U2 e9 e& w
4.2.b ii IPv4 Access Control Lists; `4 a1 D3 _% e9 `: ^
4.2.b iii Unicast Reverse Path Forwarding- `, O$ z4 [/ R: P: l
4.2.c IPv6 infrastructure security features
. |2 k2 {( O! }0 S4.2.c i RA Guard- y" s2 Y+ R, h3 q) K& {
4.2.c ii DHCP Guard% S' @' w" P0 A: j) j4 [
4.2.c iii Binding table; X: e/ H, T3 r% C
4.2.c iv Device tracking
* V" T! {9 q( [3 p( }3 [4.2.c v ND Inspection/Snooping$ K0 I' Z5 a' `) ^3 x: ^+ `
4.2.c vi Source Guard
: R$ _# H8 E$ \( J5 @4.2.d IEEE 802.1X Port-Based Authentication
& H9 W) e/ t9 Y% p# f4.2.d i Device roles, port states
1 P6 R/ Z1 A+ @% F4.2.d ii Authentication process( a, V& r1 s1 t; v2 g9 R
4.2.d iii Host modes
& c9 g X$ F% P( l9 w; y8 O4.3 System Management( W6 a( Q, a9 q% N4 L
4.3.a Device management
' P& x C( H- G$ W T2 K4.3.a i Console and VTY
4 U j) @- W5 S! M5 d4.3.a ii SSH, SCP
8 r. n7 q4 N0 X( ?# W4.3.a iii RESTCONF, NETCONF
$ }' L: M, s+ }& b. F; B* L4.3.b SNMP; a' `2 q7 O% X" `1 g2 T6 s
4.3.b i v2c
" }# D) T% P# {) p, O4.3.b ii v3/ M% c; E h R5 B5 z# a# V2 ?; G
4.3.c Logging
8 Z- ^! ~* e3 a: [( h4 l4.3.c i Local logging, syslog, debugs, conditional debugs: G4 `7 p; ]# o' F6 j. U; }3 u
4.3.c ii Timestamps2 d) F1 ]* h" ?
4.4 Quality of Service
( v- f0 Q; N" h' U6 E+ O4.4.a End to end L3 QoS using MQC8 j( Q& ?/ h0 {8 Z
4.4.a i DiffServ
# x" k, s" W4 t1 F4.4.a ii CoS and DSCP Mapping) g. O( o' G B7 X+ X; E& x6 Q
4.4.a iii Classification
* Q. s9 ^, `! G6 U& y4.4.a iv Network Based Application Recognition (NBAR)
' b4 a; ]1 T( T: M4.4.a v Marking using IP Precedence, DSCP, CoS9 U5 o6 F- A) V% l1 e5 q# h
4.4.a vi Policing, shaping
: g- u6 {' ~ e$ J4.4.a vii Congestion management and avoidance
# e/ X7 U( Q$ c4.4.a viii HQoS, Sub-rate Ethernet Link
- K p/ {- D" W' F1 E& [4.5 Network Services' E- j, |7 [! t) p& x7 n! _# ]
4.5.a First-Hop Redundancy Protocols. k4 M, A* i" l, w5 y, v$ V
4.5.a i HSRP, GLBP, VRRP' g% O6 K! F1 a) g# N) f9 s
4.5.a ii Redundancy using IPv6 RS/RA; ^# R+ C U# `5 o3 a' Y
4.5.b Network Time Protocol" q) Q, d F8 l1 t/ H; \/ |
4.5.b i Master, client
+ S; O" L' w s6 k0 Q0 U( o) N: k4.5.b ii Authentication& t+ ^1 D9 F% {- t2 K$ c' Z
4.5.c DHCP on Cisco IOS5 t5 T1 r/ P, B$ V( a, s9 P- e& M7 R
4.5.c i Client, server, relay- A1 C+ S# o$ {$ T, F
4.5.c ii Options( S3 Q- |; _2 ^/ w8 |5 M
4.5.c iii SLAAC/DHCPv6 interaction* y" @$ Z1 p7 H# {/ r. }6 D4 m! T
4.5.c iv Stateful, stateless DHCPv6% ^ [' c& F. K* |8 L, m) i
4.5.c v DHCPv6 Prefix Delegation
9 k. s$ `1 a. |3 T4.5.d IPv4 Network Address Translation" e8 z$ m" h- ] b% a: [5 s
4.5.d i Static NAT, PAT
$ E, `* T8 X2 [& }6 D4.5.d ii Dynamic NAT, PAT
! Z+ L3 e( c% f4 x4.5.d iii Policy-based NAT, PAT8 C3 M# f* g0 `& a" F& `
4.5.d iv VRF aware NAT, PAT
7 m2 c: |6 k- T/ N r) I7 r8 D4.5.d v IOS-XE VRF-Aware Software Infrastructure (VASI) NAT
& N1 ~1 x) Q. T$ `2 _4.6 Network optimization
8 f4 {1 \" W2 Z3 G" e( D+ n4.6.a IP SLA1 W1 l; m& A3 {
4.6.a i ICMP probes
* F3 ^! e) H! a4.6.a ii UDP probes
$ }7 p" c- @+ \4 N9 y4.6.a iii TCP probes1 l. | N& l0 z' c. `
4.6.b Tracking object$ K4 b2 s1 J& m$ r9 S
4.6.c Flexible Netflow
! [8 d. e: l3 I; G+ n: b4.7 Network operations
% p3 T: M, b9 L t$ o% E4.7.a Traffic capture
$ ^: x2 U, ~) c0 [$ L* c# h0 ?4.7.a i SPAN
- q2 j }1 `! w' o& u4 n: d4.7.a ii RSPAN
+ W; g( [- ]# |4.7.a iii ERSPAN1 B! C" y. z9 r6 m7 p) f& Y3 C
4.7.a iv Embedded Packet Capture
4 l9 E" n2 K: S3 }- [0 [- K- w4.7.b Cisco IOS-XE troubleshooting tools# ~6 {$ a3 L" H% a" h# B
4.7.b i Packet Trace
S4 Y$ N o9 q6 O" N4.7.b ii Conditional debugger (debug platform condition)
9 @% N' q6 t- B6 r/ _( W; N" J5 v6 J
第五部分 infrastructure automation and programmability 15%
# h, f/ P2 @! Z, u$ t& b' e5.1 Data encoding formats8 |0 X& s1 l2 X4 F
5.1.a JSON
/ C" [6 z) [$ _* `2 s- ^5.1.b XML R2 h+ u/ |/ ^/ y- m! }. U
5.2 Automation and scripting9 w/ t$ S9 m. L, ?
5.2.a EEM applets9 g- U. R5 a( p& s" N) b
5.2.b Guest shell! r6 m L" {& j3 w) r- \
5.2.b i Linux environment7 n% e9 }- t* r% V
5.2.b ii CLI Python module
* J4 {5 R+ V2 L8 ?2 d5.2.b iii EEM Python module; R7 U0 w8 T& ~5 x+ r. Z, }
5.3 Programmability
* V# c/ |. U. T- @" ]' I& [. `5.3.a Interaction with vManage API
+ F$ o2 O: R5 P5.3.a i Python requests library and Postman
/ L: d( h$ \+ q5.3.a ii Monitoring endpoints* \5 c- o# C8 M$ T8 C% y
5.3.a iii Configuration endpoints3 l, a1 U# d5 v8 h8 w: G {
5.3.b Interaction with Cisco DNA Center API
+ z3 H( P% x) o( Z5.3.b i HTTP request (GET, PUT, POST) via Python requests library and Postman1 F; ?# A4 } r3 _) [1 ?
5.3.c Interaction with Cisco IOS XE API
2 [& U ~% Z7 x. M5.3.c i Via NETCONF/YANG using Python ncclient library- x+ `" o# |+ z! N3 W
5.3.c ii Via RESTCONF/YANG using Python requests library and Postman
9 Z* B# f# D9 _( v, j5.3.d Deploy and verify model-driven telemetry" J' a7 n5 A/ L* ?1 [% ~, U
5.3.d i Configure on-change subscription using gRPC1 R" g% |& B; f7 h& z1 [9 K' a
8 b. H @; q: ~( ]5 G; r# i$ x
) L" E) U$ D; q: P7 q
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