diff mbox series

[v1,5/7] doc: drop images full paths, we have imagesdir properly set

Message ID 1498694405-16518-6-git-send-email-odpbot@yandex.ru
State Superseded
Headers show
Series [v1,1/7] doc: add IMAGES_DIR instead of specifying full path to images | expand

Commit Message

Github ODP bot June 29, 2017, midnight UTC
From: Dmitry Eremin-Solenikov <dmitry.ereminsolenikov@linaro.org>


Signed-off-by: Dmitry Eremin-Solenikov <dmitry.ereminsolenikov@linaro.org>

---
/** Email created from pull request 61 (lumag:docs-fix)
 ** https://github.com/Linaro/odp/pull/61
 ** Patch: https://github.com/Linaro/odp/pull/61.patch
 ** Base sha: 9b78da8e2373ab0530cfbbd72b2229059b57ddf1
 ** Merge commit sha: beb74541650c77e8682b58cfcdb8424e62c5b053
 **/
 doc/users-guide/users-guide-pktio.adoc | 14 +++++++-------
 doc/users-guide/users-guide-tm.adoc    |  4 ++--
 2 files changed, 9 insertions(+), 9 deletions(-)
diff mbox series

Patch

diff --git a/doc/users-guide/users-guide-pktio.adoc b/doc/users-guide/users-guide-pktio.adoc
index 9ca91f76..80a58d2f 100644
--- a/doc/users-guide/users-guide-pktio.adoc
+++ b/doc/users-guide/users-guide-pktio.adoc
@@ -10,7 +10,7 @@  PktIO objects are manipulated through various state transitions via
 `odp_pktio_xxx()` API calls as shown below:
 
 .ODP PktIO Finite State Machine
-image::../images/pktio_fsm.svg[align="center"]
+image::pktio_fsm.svg[align="center"]
 
 PktIOs begin in the *Unallocated* state. From here a call `odp_pktio_open()`
 is used to create an *odp_pktio_t* handle that is used in all subsequent calls
@@ -159,7 +159,7 @@  maximum flexibility to the data plane application writer.
 The processing of DIRECT input is shown below:
 
 .PktIO DIRECT Mode Receive Processing
-image::../images/pktin_direct_recv.svg[align="center"]
+image::pktin_direct_recv.svg[align="center"]
 
 In DIRECT mode, received packets are stored in one or more special PktIO queues
 of type *odp_pktin_queue_t* and are retrieved by threads calling the
@@ -376,7 +376,7 @@  to structure itself.
 A PktIO operating in DIRECT mode performs TX processing as shown here:
 
 .PktIO DIRECT Mode Transmit Processing
-image::../images/pktout_direct_send.svg[align="center"]
+image::pktout_direct_send.svg[align="center"]
 
 Direct TX processing operates similarly to Direct RX processing. Following
 open, the `odp_pktout_queue_config()` API is used to create and configure
@@ -501,7 +501,7 @@  QUEUE mode uses standard ODP event queues to service packets.
 The processing for QUEUE input processing is shown below:
 
 .PktIO QUEUE Mode Receive Processing
-image::../images/pktin_queue_recv.svg[align="center"]
+image::pktin_queue_recv.svg[align="center"]
 
 In QUEUE mode, received packets are stored in one or more standard ODP queues.
 The difference is that these queues are not created directly by the
@@ -550,7 +550,7 @@  with the PktIO.
 Transmit processing for PktIOs operating in QUEUE mode is shown below:
 
 .PktIO QUEUE Mode Transmit Processing
-image::../images/pktout_queue_send.svg[align="center]
+image::pktout_queue_send.svg[align="center]
 
 For TX processing QUEUE mode behaves similar to DIRECT mode except that
 output queues are regular ODP event queues that receive packets via
@@ -578,7 +578,7 @@  input queues created by a subsequent `odp_pktin_queue_config()` call are to
 be used as input to the *ODP Scheduler*.
 
 .PktIO SCHED Mode Receive Processing
-image::../images/pktin_sched_recv.svg[align="center']
+image::pktin_sched_recv.svg[align="center']
 
 For basic use, SCHED mode simply associates the PktIO input event queues
 created by `odp_pktin_queue_config()` with the scheduler. Hashing may still be
@@ -593,7 +593,7 @@  In its fullest form, PktIOs operating in SCHED mode use the *ODP Classifier*
 to permit fine-grained flow separation on *Class of Service (CoS)* boundaries.
 
 .PktIO SCHED Mode Receive Processing with Classification
-image::../images/pktin_sched_cls.svg[align="center"]
+image::pktin_sched_cls.svg[align="center"]
 
 In this mode of operation, the hash function of `odp_pktin_queue_config()` is
 typically not used. Instead, the event queues created by this call,
diff --git a/doc/users-guide/users-guide-tm.adoc b/doc/users-guide/users-guide-tm.adoc
index 36fa9ece..25129733 100644
--- a/doc/users-guide/users-guide-tm.adoc
+++ b/doc/users-guide/users-guide-tm.adoc
@@ -162,7 +162,7 @@  into one fan-in of a subsequent tm_node or egresss object - forming a proper
 tree.
 
 .Hierarchical Scheduling
-image::../images/tm_hierarchy.svg[align="center"]
+image::tm_hierarchy.svg[align="center"]
 
 Multi-level/hierarchical scheduling adds both great control and significant
 complexity.  Logically, despite the implication of the tm_node tree diagrams,
@@ -183,7 +183,7 @@  some very sophisticated behaviours. Each tm_node can contain a set of scheduler
 shaper and a WRED component - or a subset of these.
 
 .Traffic Manager Node
-image::../images/tm_node.svg[align="center"]
+image::tm_node.svg[align="center"]
 
 In its full generality an tm_node consists of a set of "fan-in" connections to
 preceding tm_queues or tm_nodes.  The fan-in for a single tm_node can range