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-rw-r--r--docs/gettingstarted/developers/bihash.md2
-rw-r--r--docs/gettingstarted/developers/binary_api_support.rst2
-rw-r--r--docs/gettingstarted/developers/building.rst2
-rw-r--r--docs/gettingstarted/developers/buildsystem/buildrootmakefile.rst2
-rw-r--r--docs/gettingstarted/developers/fib20/dataplane.rst2
-rw-r--r--docs/gettingstarted/developers/fib20/graphwalks.rst6
-rw-r--r--docs/gettingstarted/developers/fib20/routes.rst18
-rw-r--r--docs/gettingstarted/developers/fib20/scale.rst2
-rw-r--r--docs/gettingstarted/developers/fib20/tunnels.rst2
-rw-r--r--docs/gettingstarted/developers/gdb_examples.rst2
-rw-r--r--docs/gettingstarted/developers/infrastructure.md2
-rw-r--r--docs/gettingstarted/developers/metadata.md16
-rw-r--r--docs/gettingstarted/developers/multiarch/index.rst2
-rw-r--r--docs/gettingstarted/developers/vnet.md8
-rw-r--r--docs/gettingstarted/developers/vpp_api_module.rst4
15 files changed, 36 insertions, 36 deletions
diff --git a/docs/gettingstarted/developers/bihash.md b/docs/gettingstarted/developers/bihash.md
index a0d652f4f6c..bc4dc1b1b34 100644
--- a/docs/gettingstarted/developers/bihash.md
+++ b/docs/gettingstarted/developers/bihash.md
@@ -74,7 +74,7 @@ search across 2**log2_size backing pages on a per-bucket basis.
To maintain *space* efficiency, we should configure the bucket array
so that backing pages are effectively utilized. Lookup performance
-tends to change *very litte* if the bucket array is too small or too
+tends to change *very little* if the bucket array is too small or too
large.
Bihash depends on selecting an effective hash function. If one were to
diff --git a/docs/gettingstarted/developers/binary_api_support.rst b/docs/gettingstarted/developers/binary_api_support.rst
index 9c17a734e44..732ce978daa 100644
--- a/docs/gettingstarted/developers/binary_api_support.rst
+++ b/docs/gettingstarted/developers/binary_api_support.rst
@@ -93,7 +93,7 @@ implement a variety of features:
* Barrier synchronization of worker threads across thread-unsafe message handlers.
Correctly-coded message handlers know nothing about the transport used
-to deliver messages to/from VPP. It's reasonably straighforward to use
+to deliver messages to/from VPP. It's reasonably straightforward to use
multiple API message transport types simultaneously.
For historical reasons, binary api messages are (putatively) sent in
diff --git a/docs/gettingstarted/developers/building.rst b/docs/gettingstarted/developers/building.rst
index 3c6c3b96e8f..4d7af16bc18 100644
--- a/docs/gettingstarted/developers/building.rst
+++ b/docs/gettingstarted/developers/building.rst
@@ -164,7 +164,7 @@ Once the packages are built they can be found in the build-root directory.
vpp-plugins_18.07-rc0~456-gb361076_amd64.deb
Finally, the created packages can be installed using the following commands. Install
-the package that correspnds to OS that VPP will be running on:
+the package that corresponds to OS that VPP will be running on:
For Ubuntu:
diff --git a/docs/gettingstarted/developers/buildsystem/buildrootmakefile.rst b/docs/gettingstarted/developers/buildsystem/buildrootmakefile.rst
index 089c15afefd..6963aecb9f3 100644
--- a/docs/gettingstarted/developers/buildsystem/buildrootmakefile.rst
+++ b/docs/gettingstarted/developers/buildsystem/buildrootmakefile.rst
@@ -156,7 +156,7 @@ Here are the contents of .../build-data/platforms/vpp.mk:
vpp_uses_dpdk = yes
- # Uncoment to enable building unit tests
+ # Uncomment to enable building unit tests
# vpp_enable_tests = yes
vpp_root_packages = vpp vom
diff --git a/docs/gettingstarted/developers/fib20/dataplane.rst b/docs/gettingstarted/developers/fib20/dataplane.rst
index 2a728c5a89a..a9e2bf27d69 100644
--- a/docs/gettingstarted/developers/fib20/dataplane.rst
+++ b/docs/gettingstarted/developers/fib20/dataplane.rst
@@ -68,7 +68,7 @@ stacking occurs, the necessary VLIB graph arcs are automatically constructed
from the respected DPO type's registered graph nodes.
The diagrams above show that for any given route the full data-plane graph is
-known before anypacket arrives. If that graph is composed of n objects, then the
+known before any packet arrives. If that graph is composed of n objects, then the
packet will visit n nodes and thus incur a forwarding cost of approximately n
times the graph node cost. This could be reduced if the graph were *collapsed*
into a single DPO and associated node. However, collapsing a graph removes the
diff --git a/docs/gettingstarted/developers/fib20/graphwalks.rst b/docs/gettingstarted/developers/fib20/graphwalks.rst
index e931c7ee70d..36fdb3f2723 100644
--- a/docs/gettingstarted/developers/fib20/graphwalks.rst
+++ b/docs/gettingstarted/developers/fib20/graphwalks.rst
@@ -15,8 +15,8 @@ child to parent relationship is thus fully known to the child, and hence a forwa
walk of the graph (from child to parent) is trivial. However, a parent does not choose
its children, it does not even choose the type. All object types that form part of the
FIB control plane graph all inherit from a single base class14; *fib_node_t*. A *fib_node_t*
-indentifies the object's index and its associated virtual function table provides the
-parent a mechanism to Զisitՠthat object during the walk. The reason for a back-walk
+identifies the object's index and its associated virtual function table provides the
+parent a mechanism to visit that object during the walk. The reason for a back-walk
is to inform all children that the state of the parent has changed in some way, and
that the child may itself need to update.
@@ -65,7 +65,7 @@ Choosing between a synchronous and an asynchronous walk is therefore a trade-off
time it takes to propagate a change in the parent to all of its children, versus the
time it takes to act on a single route update. For example, if a route update where to
affect millions of child recursive routes, then the rate at which such updates could be
-processed would be dependent on the number of child recursive route Рwhich would not be
+processed would be dependent on the number of child recursive route which would not be
good. At the time of writing FIB2.0 uses synchronous walk in all locations except when
walking the children of a path-list, and it has more than 32 [#f15]_ children. This avoids the
case mentioned above.
diff --git a/docs/gettingstarted/developers/fib20/routes.rst b/docs/gettingstarted/developers/fib20/routes.rst
index 62fcc00bd78..464a24af5d3 100644
--- a/docs/gettingstarted/developers/fib20/routes.rst
+++ b/docs/gettingstarted/developers/fib20/routes.rst
@@ -10,19 +10,19 @@ the route is resolved as the graph is complete from *fib_entry_t* to *ip_adjacen
In some routing models a VRF will consist of a set of tables for IPv4 and IPv6, and
unicast and multicast. In VPP there is no such grouping. Each table is distinct from
-each other. A table is indentified by its numerical ID. The ID range is separate for
+each other. A table is identified by its numerical ID. The ID range is separate for
each address family.
A table is comprised of two route data-bases; forwarding and non-forwarding. The
forwarding data-base contains routes against which a packet will perform a longest
prefix match (LPM) in the data-plane. The non-forwarding DB contains all the routes
-with which VPP has been programmed Рsome of these routes may be unresolved for reasons
+with which VPP has been programmed some of these routes may be unresolved for reasons
that prevent their insertion into the forwarding DB
(see section: Adjacency source FIB entries).
The route data is decomposed into three parts; entry, path-list and paths;
-* The *fib_entry_t*, which contains the routeճ prefix, is representation of that prefix's entry in the FIB table.
+* The *fib_entry_t*, which contains the routes prefix, is representation of that prefix's entry in the FIB table.
* The *fib_path_t* is a description of where to send the packets destined to the route's prefix. There are several types of path.
* Attached next-hop: the path is described with an interface and a next-hop. The next-hop is in the same sub-net as the router's own address on that interface, hence the peer is considered to be *attached*
@@ -37,10 +37,10 @@ The route data is decomposed into three parts; entry, path-list and paths;
.. figure:: /_images/fib20fig2.png
-Figure 2: Route data model Рclass diagram
+Figure 2: Route data model class diagram
Figure 2 shows an example of a route with two attached-next-hop paths. Each of these
-paths will *resolve* by finding the adjacency that matches the pathճ attributes, which
+paths will *resolve* by finding the adjacency that matches the paths attributes, which
are the same as the key for the adjacency data-base [#f3]_. The *forwarding information (FI)*
is the set of adjacencies that are available for load-balancing the traffic in the
data-plane. A path *contributes* an adjacency to the route's forwarding information, the
@@ -68,10 +68,10 @@ forwarding information of multiple sources to be combined. Instead the FIB must
to use the forwarding information from only one source. This choice is based on a static
priority assignment [#f4]_. The FIB must maintain the information each source has added
so it can be restored should that source become the best source. VPP has two
-*control-plane* sources; the API and the CLI Рthe API has the higher priority.
+*control-plane* sources; the API and the CLI the API has the higher priority.
Each *source* data is represented by a *fib_entry_src_t* object of which a
*fib_entry_t* maintains a sorted vector.n A prefix is *connected* when it is
-applied to a routerճ interface.
+applied to a routers interface.
The following configuration:
@@ -84,7 +84,7 @@ attached, and 192.168.1.1/32 which is connected and local (a.k.a receive or for-
Both prefixes are *interface* sourced. The interface source has a high priority, so
the accidental or nefarious addition of identical prefixes does not prevent the
router from correctly forwarding. Packets matching a connected prefix will
-generate an ARP request for the packetճ destination address, this process is known
+generate an ARP request for the packets destination address, this process is known
as a *glean*.
An *attached* prefix also results in a glean, but the router does not have its own
@@ -147,7 +147,7 @@ So while the following configuration is accepted:
$ ip arp 192.168.1.2 GigabitEthernet0/8/0 dead.dead.dead
$ set interface ip table GigabitEthernet0/8/0 2
-it does not result in the desired behaviour, where the adj-fib and connecteds are
+it does not result in the desired behaviour, where the adj-fib and connected adjacencies are
moved to table 2.
Recursive Routes
diff --git a/docs/gettingstarted/developers/fib20/scale.rst b/docs/gettingstarted/developers/fib20/scale.rst
index c97297d4adc..8cee1f1835c 100644
--- a/docs/gettingstarted/developers/fib20/scale.rst
+++ b/docs/gettingstarted/developers/fib20/scale.rst
@@ -93,7 +93,7 @@ IP6 Heap
The IPv6 heap is used to allocate the memory needed for the
data-structure within which the IPv6 prefixes are stored. IPv6 also
has the concept of forwarding and non-forwarding entries, however for
-IPv6 all the forwardind entries are stored in a single hash table
+IPv6 all the forwarding entries are stored in a single hash table
(same goes for the non-forwarding). The key to the hash table includes
the IPv6 table-id.
diff --git a/docs/gettingstarted/developers/fib20/tunnels.rst b/docs/gettingstarted/developers/fib20/tunnels.rst
index 4c1dfe2a07d..1613a69df8c 100644
--- a/docs/gettingstarted/developers/fib20/tunnels.rst
+++ b/docs/gettingstarted/developers/fib20/tunnels.rst
@@ -23,7 +23,7 @@ graph/chain rather than its usual terminal location.
The mid-chain adjacency is contributed by the gre_tunnel_t , which also becomes
part of the FIB control-plane graph. Consequently it will be visited by a
-back-walk when the forwarding information for the tunnelճ destination changes.
+back-walk when the forwarding information for the tunnel's destination changes.
This will trigger it to restack the mid-chain adjacency on the new
*load_balance_t* contributed by the parent *fib_entry_t*.
diff --git a/docs/gettingstarted/developers/gdb_examples.rst b/docs/gettingstarted/developers/gdb_examples.rst
index 71340dabcd0..893987796cf 100644
--- a/docs/gettingstarted/developers/gdb_examples.rst
+++ b/docs/gettingstarted/developers/gdb_examples.rst
@@ -32,7 +32,7 @@ or abort signal, then you can run the VPP debug binary and then execute **backtr
(gdb) bt
#0 ip4_icmp_input (vm=0x7ffff7b89a40 <vlib_global_main>, node=0x7fffb6bb6900, frame=0x7fffb6725ac0) at /scratch/vpp-master/build-data/../src/vnet/ip/icmp4.c:187
#1 0x00007ffff78da4be in dispatch_node (vm=0x7ffff7b89a40 <vlib_global_main>, node=0x7fffb6bb 6900, type=VLIB_NODE_TYPE_INTERNAL, dispatch_state=VLIB_NODE_STATE_POLLING, frame=0x7fffb6725ac0, last_time_stamp=10581236529 65565) at /scratch/vpp-master/build-data/../src/vlib/main.c:988
- #2 0x00007ffff78daa77 in dispatch_pending_node (vm=0x7ffff7b89a40 <vlib_global_main>, pending_f rame_index=6, last_time_stamp=1058123652965565) at /scratch/vpp-master/build-data/../src/vlib/main.c:1138
+ #2 0x00007ffff78daa77 in dispatch_pending_node (vm=0x7ffff7b89a40 <vlib_global_main>, pending_frame_index=6, last_time_stamp=1058123652965565) at /scratch/vpp-master/build-data/../src/vlib/main.c:1138
....
Get to the GDB prompt
diff --git a/docs/gettingstarted/developers/infrastructure.md b/docs/gettingstarted/developers/infrastructure.md
index 95465f0a1e2..2c798f4a337 100644
--- a/docs/gettingstarted/developers/infrastructure.md
+++ b/docs/gettingstarted/developers/infrastructure.md
@@ -161,7 +161,7 @@ format specification. For example:
format\_junk() can invoke other user-format functions if desired. The
programmer shoulders responsibility for argument type-checking. It is
-typical for user format functions to blow up spectaculary if the
+typical for user format functions to blow up spectacularly if the
va\_arg(va, type) macros don't match the caller's idea of reality.
Unformat
diff --git a/docs/gettingstarted/developers/metadata.md b/docs/gettingstarted/developers/metadata.md
index 1f7f5c72bcf..2f20596c0d9 100644
--- a/docs/gettingstarted/developers/metadata.md
+++ b/docs/gettingstarted/developers/metadata.md
@@ -31,7 +31,7 @@ the pre-data (rewrite space) area.
* VNET_BUFFER_F_L4_CHECKSUM_COMPUTED: tcp/udp checksum has been computed
* VNET_BUFFER_F_L4_CHECKSUM_CORRECT: tcp/udp checksum is correct
* VNET_BUFFER_F_VLAN_2_DEEP: two vlan tags present
- * VNET_BUFFER_F_VLAN_1_DEEP: one vlag tag present
+ * VNET_BUFFER_F_VLAN_1_DEEP: one vlan tag present
* VNET_BUFFER_F_SPAN_CLONE: packet has already been cloned (span feature)
* VNET_BUFFER_F_LOOP_COUNTER_VALID: packet look-up loop count valid
* VNET_BUFFER_F_LOCALLY_ORIGINATED: packet built by vpp
@@ -48,13 +48,13 @@ the pre-data (rewrite space) area.
* VNET_BUFFER_F_IS_DVR: packet to be reinjected into the l2 output path
* VNET_BUFFER_F_QOS_DATA_VALID: QoS data valid in vnet_buffer_opaque2
* VNET_BUFFER_F_GSO: generic segmentation offload requested
- * VNET_BUFFER_F_AVAIL1: avaliable bit
- * VNET_BUFFER_F_AVAIL2: avaliable bit
- * VNET_BUFFER_F_AVAIL3: avaliable bit
- * VNET_BUFFER_F_AVAIL4: avaliable bit
- * VNET_BUFFER_F_AVAIL5: avaliable bit
- * VNET_BUFFER_F_AVAIL6: avaliable bit
- * VNET_BUFFER_F_AVAIL7: avaliable bit
+ * VNET_BUFFER_F_AVAIL1: available bit
+ * VNET_BUFFER_F_AVAIL2: available bit
+ * VNET_BUFFER_F_AVAIL3: available bit
+ * VNET_BUFFER_F_AVAIL4: available bit
+ * VNET_BUFFER_F_AVAIL5: available bit
+ * VNET_BUFFER_F_AVAIL6: available bit
+ * VNET_BUFFER_F_AVAIL7: available bit
* u32 flow_id: generic flow identifier
* u8 ref_count: buffer reference / clone count (e.g. for span replication)
* u8 buffer_pool_index: buffer pool index which owns this buffer
diff --git a/docs/gettingstarted/developers/multiarch/index.rst b/docs/gettingstarted/developers/multiarch/index.rst
index a1dfe98bd62..824a8e68438 100644
--- a/docs/gettingstarted/developers/multiarch/index.rst
+++ b/docs/gettingstarted/developers/multiarch/index.rst
@@ -3,7 +3,7 @@
Multi-architecture support
==========================
-This reference guide describes how to use the vpp muli-architecture support scheme
+This reference guide describes how to use the vpp multi-architecture support scheme
.. toctree::
:maxdepth: 1
diff --git a/docs/gettingstarted/developers/vnet.md b/docs/gettingstarted/developers/vnet.md
index 89169efb8d4..f9d7bd597fa 100644
--- a/docs/gettingstarted/developers/vnet.md
+++ b/docs/gettingstarted/developers/vnet.md
@@ -325,7 +325,7 @@ these data to easily filter/track single packets as they traverse the
forwarding graph.
Multiple records per packet are normal, and to be expected. Packets
-will appear multipe times as they traverse the vpp forwarding
+will appear multiple times as they traverse the vpp forwarding
graph. In this way, vpp graph dispatch traces are significantly
different from regular network packet captures from an end-station.
This property complicates stateful packet analysis.
@@ -494,7 +494,7 @@ These commands have the following optional parameters:
capture is off.
- <b>max-bytes-per-pkt _nnnn_</b> - maximum number of bytes to trace
- on a per-paket basis. Must be >32 and less than 9000. Default value:
+ on a per-packet basis. Must be >32 and less than 9000. Default value:
512.
- <b>filter</b> - Use the pcap rx / tx / drop trace filter, which must
@@ -529,7 +529,7 @@ These commands have the following optional parameters:
The "classify filter pcap | <interface-name> " debug CLI command
constructs an arbitrary set of packet classifier tables for use with
"pcap rx | tx | drop trace," and with the vpp packet tracer on a
-per-interrface basis.
+per-interface basis.
Packets which match a rule in the classifier table chain will be
traced. The tables are automatically ordered so that matches in the
@@ -538,7 +538,7 @@ most specific table are tried first.
It's reasonably likely that folks will configure a single table with
one or two matches. As a result, we configure 8 hash buckets and 128K
of match rule space by default. One can override the defaults by
-specifiying "buckets <nnn>" and "memory-size <xxx>" as desired.
+specifying "buckets <nnn>" and "memory-size <xxx>" as desired.
To build up complex filter chains, repeatedly issue the classify
filter debug CLI command. Each command must specify the desired mask
diff --git a/docs/gettingstarted/developers/vpp_api_module.rst b/docs/gettingstarted/developers/vpp_api_module.rst
index 261c8691dc2..3cdea524e4e 100644
--- a/docs/gettingstarted/developers/vpp_api_module.rst
+++ b/docs/gettingstarted/developers/vpp_api_module.rst
@@ -56,7 +56,7 @@ _______
**Low-level API**
-Refer to inline API documentation in doxygen format in vapi.h header for description of functions. It's recommened to use the safer, high-level API provided by specialized headers (e.g. vpe.api.vapi.h or vpe.api.vapi.hpp).
+Refer to inline API documentation in doxygen format in vapi.h header for description of functions. It's recommended to use the safer, high-level API provided by specialized headers (e.g. vpe.api.vapi.h or vpe.api.vapi.hpp).
**C high-level API**
@@ -113,7 +113,7 @@ _________
*Create a Connection and execute the appropriate Request to subscribe to events (e.g. Want_stats)*
-#. Create an Event_registration with a template argument being the type of event you are insterested in.
+#. Create an Event_registration with a template argument being the type of event you are interested in.
#. Call dispatch() or wait_for_response() to wait for the event. A callback will be called when an event occurs (if passed to Event_registration() constructor). Alternatively, read the result set.
.. note::